Method and system for manipulation  of audio or video signals

ABSTRACT

A method and system for manipulation of audio or video signals.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No. 10/820,995 filed Apr. 8, 2004, which is a divisional of U.S. patent application Ser. No. 09/469,802 filed Dec. 22, 1999, now U.S. Pat. No. 6,721,491 issued Apr. 13, 2004, which is a divisional of U.S. patent application Ser. No. 08/811,266 filed Mar. 4, 1997, now U.S. Pat. No. 6,014,491 issued Jan. 11, 2000.

FIELD OF THE INVENTION

The present invention is related to a method and system to compress, and/or convert, audio and video signals, or files, into a static file format, and more particularly to a method and system to playback, and/or replicate, static audio files using a static audio player; and/or to playback, and/or replicate, static video files using a static video player.

BACKGROUND OF THE INVENTION

Generally, computer file formats for digital audio (hereinafter referred to as a “Dynamic Audio File”), such as the AUI, WAV, etc. audio file formats, and digital video (hereinafter referred to as a “Dynamic Video File”), such as the MPEG video file format, are formatted in a dynamic manner permitting easy and routine editing, serving a very useful purpose in the music and movie industries. Unfortunately, the dynamic nature of these file formats results in the generation of very large computer file sizes (i.e. hundreds of millions of bytes in size for a 40 minute digital audio file of 44.1 kHz sound quality and multi Gigabytes of data for full length motion picture quality recordings in digital video form).

As example, each second of a CD quality Dynamic Audio File is divided into 44,100 discrete time intervals. Each of these time intervals can simultaneously contain multiple frequencies (i.e. pitch) of sound at multiple amplitudes (i.e. volume). The Dynamic Audio File instructs an audio playing device (hereinafter referred to as a “Dynamic Audio Player”) to play discrete frequencies/amplitudes at a rate of 44,100 times per second for CD quality sound. In a Dynamic Audio File, even if a string of consecutive time intervals contains identical frequencies and their related amplitudes, such an occurrence is irrelevant since the Digital Audio File format was designed, in part, to enable specific editing and/or dynamic manipulation of each individual time interval. The Dynamic Audio File fails to take advantage of redundancies within a string of consecutive time intervals which happen to repeat one or more identical frequencies and their related amplitudes.

Additionally, motion picture quality Digital Video Files are generally composed of about 30 video frames (images) per second. Each of these video frames are composed of a two dimensional, usually rectangular or square, grid of pixels. Each such pixel is capable of being colorized by complex, and/or basic, colors. Usually, a complex color is generated by mixing distinct shades of the basic colors red, green, and blue. The greater the number of distinct shades of these three basic colors, the greater the color definition of the video recording. It is common practice to use 256 distinct shades of the basic colors red, green, and blue in combination to create a palette of 16,777,216 unique complex colors, which is more than enough complex colors to display a motion picture quality recording. As example, each pixel contains a numeric entry ranging from 000 to 255 to define a distinct shade of the basic color red, a numeric entry ranging from 000 to 255 to define a distinct shade of the basic color green, and a numeric entry ranging from 000 to 255 to define a distinct shade of the basic color blue, all three of these shades of the basic colors red, green, and blue combine to identify a specific complex color from the palette of 16,777,216 possible complex colors (i.e. 256×256×256=16,777,216). Furthermore, the complex color white is defined, as is customary, as the mixture of the basic colors red₂₅₅, green₂₅₅, and blue₂₅₅, where the subscript defines the distinct shade; and the complex color black is defined, as is customary, as the mixture of the basic colors red₀₀₀, green₀₀₀, and blue₀₀₀. Using this manner to mathematically describe complex colors, red₁₁₆, green₀₀₀, and blue₀₉₅ mix to generate a discrete shade of purple. This manner to mathematically describe complex colors will be used throughout the teachings of the present invention.

The Dynamic Video File instructs a video playing device (hereinafter referred to as the “Dynamic Video Player”) to display specific complex colors within each discrete pixel of each discrete video frame video frame of the video recording. In a Dynamic Video File, even if a string of consecutive video frames contains a pixel having the identical complex color, such a coincidence is irrelevant since the Digital Video File format was designed, in part, to enable very specific and independent editing or dynamic manipulation of each individual discrete pixel within each discrete video frame. The Dynamic Video File format fails to take advantage of similarities or redundancies within a string of consecutive video frames in which the color within discrete pixels remains constant over time.

Furthermore, use of the Dynamic Audio File and Dynamic Video File formats pose several problems when used to electronically distribute digital audio and digital video signals to the consumer markets (i.e. U.S. Pat. No. 5,191,573). The Dynamic Audio File and the Dynamic Video File formats, being very large as measured in bytes of data, require considerable time to transmit via telecommunications. Additionally, and as example, if the user desires to save Dynamic Audio Files in the home, a massive storage device would be required (i.e. 10 music albums of about 45 minutes in duration each, in AUI format, would require in excess of 7 Giga bytes of storage capacity).

SUMMARY OF THE INVENTION

The present invention offers a new and improved method and system to encode audio and video files in a static format for playback utilizing a static player. The static format takes advantage of consecutive redundancies within Dynamic Audio Files and Dynamic Video Files, with respect to time.

A static audio file (hereinafter referred to as the “Static Audio File”) is encoded in a format which records a plurality of discrete frequency/amplitude (sound) information to be played, and/or replicated, on an audio output device, and the related starting points each such frequency/amplitude is to be played, and/or replicated, for one or more consecutive time interval, with respect to time. The Static Audio File provides instructions enabling a audio playing device (hereinafter referred to as the “Static Audio Player”) to save, and/or replace, such frequency/amplitude information in a matrix of memory registers within the Static Audio Player. Upon instruction from the user, the Static Audio Player will commence the playback process whereby each such frequency/amplitude, generated from each such memory register, will commence to be played on an audio output device, commencing with a discrete time interval. The Static Audio Player continues to play, and/or replicate, each such frequency/amplitude, generated from each such memory register, on an audio output device in each subsequent time interval (generally about 44,100 time intervals per second for CD quality sound), without further instruction from the Static Audio File. If, and/or when, the Static Audio Player receives subsequent instructions from the Static Audio File to update the frequency/amplitude information in any such memory register with new frequency/amplitude information corresponding with a specific time interval, then the Static Audio Player will then play, and/or replicate, such new frequency/amplitude, generated from any such updated memory register, on an audio output device starting with a subsequent time interval.

A static video file (hereinafter referred to as the “Static Video File”) is encoded in a format which records color information to be displayed, and/or replicated, within discrete pixels on a video output device, and the related starting points each such color is to be displayed, and/or replicated, within each such pixel, for one or more consecutive video frames, with respect to time. The Static Video File provides instructions enabling a video playing device (hereinafter referred to as the “Static Video Player”) to save, and/or replace, such color information in a matrix of memory registers within the Static Video Player. Upon instruction from the user, the Static Video Player will commence the playback process whereby each such color, generated from each such memory register, will commence to be displayed within the corresponding pixel on a video output device, commencing with a discrete video frame. The Static Video Player continues to display, and/or replicate, each such color, generated from each such memory register, within each such pixel on a video output device in each subsequent video frame (generally about 30 video frames per second for full motion video), without further instruction from the Static Video File. If, and/or when, the Static Video Player receives subsequent instructions from the Static Video File to update the color information in any such memory register with new color information corresponding with a specific video frame, then the Static Video Player will then display, and/or replicate, such new color, generated from any such updated memory register, within the corresponding pixel on a video output device starting with a subsequent video frame.

The present invention pertains to a method for manipulating video or audio signals. The method comprises the steps of analyzing a video or audio signal having information and a size. Then there is the step of producing a representative signal from and corresponding to the audio or video signal that identifies the audio or video signal but has less information than the audio or video signal such that the audio or video signal cannot be produced from the representative signal itself and is smaller in size than the size of the audio or video signal. Next there is the step of transmitting to a remote location the representative signal. Then there is the step of recreating the audio or video signal from the representative signal at the remote location.

The present invention pertains to an apparatus for manipulating video or audio signals. The apparatus comprises means or a mechanism for analyzing a video or audio signal having a size. The apparatus comprises means or a mechanism for producing a representative signal from and corresponding to the audio or video signal that identifies the audio or video signal but has less information than the audio or video signal and is smaller in size than the size of the audio or video signal. The producing means or mechanism is connected to the analyzing means or mechanism. The apparatus comprises means or a mechanism for transmitting to a remote location the representative signal. The transmitting means or mechanism is connected to the producing means or mechanism. The apparatus comprises means or a mechanism for recreating the audio or video signal from the representative signal at the remote location. The recreating means or mechanism is connected to the transmitting means or mechanism.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings, the preferred embodiment of the invention and preferred methods of practicing the invention are illustrated in which:

FIG. 1 is a pictorial flow chart which may be used in carrying out the teachings of this invention for the purpose of converting Dynamic Audio Files into Static Audio Files, and playback of such Static Audio Files by means of a Static Audio Player, and conversion of Static Audio Files to Dynamic Audio Files by means of a Static Audio Player; and

FIG. 2 is a pictorial flow chart which may be used in carrying out the teachings of this invention for the purpose of converting Dynamic Video Files into Static Video Files, and playback of such Static Video Files by means of a Static Video Player, and conversion of Static Video Files to Dynamic Video Files by means of a Static Video Player.

FIG. 3 is computer algorithm which details one possible configuration of the computer file format for the Static Audio File.

FIG. 4 is a computer algorithm which details one possible configuration of the computer file format for the Static Audio File.

FIG. 5 and FIG. 6 are computer algorithms which detail possible configurations of the computer file format for the Static Video File.

FIG. 7 is a graphical representation of a Dynamic Audio File 60 in which frequency F₅ is to be played at amplitudes A₁, A₂, and A₃ during time intervals I₄, I₅, I₆, and I₇ on an audio output device.

FIG. 8 is a graphical representation of the playback output of a Dynamic Audio File 60 by a Dynamic Audio Player 70 in which frequency F₅ is played at amplitudes A₁, A₂, and A₃ during time intervals I₄, I₅, I₆, and I₇ on an audio output device.

FIG. 9 is a graphical representation of a Static Audio File 110 in which frequency F₅ is to be played at amplitudes A₁, A₂, and A₃ during time intervals I₄, I₅, I₆, and I₇ on an Audio Output Device 190.

FIG. 10 is a graphical representation of the playback output of a Static Audio File 110 by a Static Audio Player 120 in which frequency F₅ is played at amplitudes A₁, A₂, and A₃ during time intervals I₄, I₅, I₆, and I₇ on an Audio Output Device 190.

FIG. 11 is a pictorial representation of the playback of a video frame F₆ of a Static Video File 310 in which a shade of purple (R₁₁₆G₀₀₀B₀₉₅) is to be displayed within pixel h₁l₁; a shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) is to be displayed within pixel h₄₁₇; and a shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) is to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390.

FIG. 12 is a computer flow chart depicting the various functions of the Frequency/Amplitude Database Compiler 80.

FIG. 13 is a computer flow chart depicting the various functions of the Dynamic to Static Audio Truncator 100.

FIG. 14 is a computer flow chart depicting the various functions of the Red/Green/Blue Database Compiler 280.

FIG. 15 is a computer flow chart depicting the various functions of the Dynamic to Static Video Truncator 300.

FIG. 16 is a graphical representation of a Dynamic Video File 260 which recorded color information to be displayed in pixels h₁l₁, h₄l₇, and h₁₁l₂₀ on a video output device.

FIG. 17 is a graphical representation of the playback output of a Dynamic Video File 260 by a Dynamic Video Player 270 which displays color information in pixels h₁l₁, h₄l₇, and h₁₁l₂₀ on a video output device.

FIG. 18 is a graphical representation of a Static Video File 310 which recorded color information to be displayed in pixels h₁l₁, h₄l₇, and h₁l₂₀ on a Video Output Device 390.

FIG. 19 is a graphical representation of the playback output of a Static Video File 310 by a Static Video Player 320 which displays color information in pixels h₁l₁, h₄l₇, and h₁₁l₂₀ on a Video Output Device 390.

FIG. 20 is a graphical representation of the playback output of a Static Video File 310 by a Static Video Player 320 which displays color information on a Video Output Device 390, said playback displaying geometric shapes mathematically defined by, and with corners located at, pixels h₃l₅, h₃l₁₈, h₈l₁₈, and h₈l₅ (Geometric Shape 1); and h₁₂l₃, h₁₂l₄, h₁₅l₄, h₁₅l₇, h₁₄l₇, h₁₄l₈, h₁₇l₈, h₁₇l₆, h₂₀l₆, h₂₀l₅, h₁₆l₅, and h₁₆l₃ (Geometric Shape 2); and h₁₂l₂₀, h₁₉l₂₀, h₁₉l₂₂, h₂₀l₂₂, h₂₀l₁₉, h₂₂l₁₉, h₂₂l₁₈, h₁₉l₁₈, h₁₉l₁₅, and h₁₇l₁₅ (Geometric Shape 3); and t₅₆ (Geometric Shape 4).

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to the drawings wherein like reference numerals refer to similar or identical parts throughout the several views, and more specifically to FIGS. 1 and 3 thereof, there is shown an apparatus 800 for manipulating video or audio signals. The apparatus comprises means or a mechanism 802 for analyzing a video or audio signal having a size. The apparatus comprises means or a mechanism 804 for producing a representative signal from and corresponding to the audio or video signal that identifies the audio or video signal but has less information than the audio or video signal and is smaller in size than the size of the audio or video signal. The producing means or mechanism is connected to the analyzing means or mechanism. The apparatus comprises means or a mechanism 806 for transmitting to a remote location the representative signal. The transmitting means or mechanism is connected to the producing means or mechanism. The apparatus comprises means or a mechanism 809 for recreating the audio or video signal from the representative signal at the remote location. The recreating means or mechanism is connected to the transmitting means or mechanism 806.

The present invention pertains to a method for manipulating video or audio signals. The method comprises the steps of analyzing a video or audio signal having information and a size. Then there is the step of producing a representative signal from and corresponding to the audio or video signal that identifies the audio or video signal but has less information than the audio or video signal such that the audio or video signal cannot be produced from the representative signal itself and is smaller in size than the size of the audio or video signal. Next there is the step of transmitting to a remote location the representative signal. Then there is the step of recreating the audio or video signal from the representative signal at the remote location.

The analyzing means or mechanism 802 can include a frequency/amplitude database compiler 80, or a red/green/blue database compiler 280. The producing means or mechanism 804 can include a dynamic to static audio truncator 100, or a dynamic to static video truncator 300. The transmitting means or mechanism 806 can include a transmitter or modem and a telecommunication connection. The recreating means or mechanism 809 can include a static audio file 110 and a sound card and a static audio player 120 and an audio output device 190, or a static video file 310 and a static video player 320 and a video output device 390.

Referring now to FIG. 1, one preferred embodiment of the invention is comprised of the following:

-   -   10 Analog Audio Source     -   20 Analog Audio Recorder     -   30 Analog Audio File     -   40 Analog to Digital Audio Converter     -   50 Analog to Digital Audio Recorder     -   60 Dynamic Audio File     -   70 Dynamic Audio Player     -   80 Frequency/Amplitude Database Compiler     -   90 Frequency/Amplitude Database     -   100 Dynamic to Static Audio Truncator     -   110 Static Audio File     -   120 Static Audio Player     -   130 Static Audio Player     -   140 Electronic Connection     -   150 Static Audio File     -   160 Dynamic Audio File     -   170 Static Audio File     -   180 Dynamic Audio File     -   190 Audio Output Device

In FIG. 1, the following components are already commercially available: the Analog Audio Source 10; the Analog Audio Recorder 20; the Analog Audio File 30; the Analog to Digital Audio Converter 40; the Analog to Digital Audio Recorder 50; the Dynamic Audio File 60, 160, and 180; the Dynamic Audio Player 70; the Electronic Connection 140; and the Audio Output Device 190.

The Frequency/Amplitude Database Compiler 80; the Frequency/Amplitude Database 90; the Dynamic to Static Audio Truncator 100; the Static Audio File 110, 150, and 170; and the Static Audio Player 120 and 130; are new teachings of this invention.

The Analog Audio Source 10 is the originating source of audio in the configuration as outlined in FIG. 1.

The Analog Audio Recorder 20 (i.e. cassette tape recorder/player, etc.) is the means by which the Analog Audio Source 10 can be recorded in either analog form or digital form.

The Analog Audio File 30 is the resulting analog file produced by the Analog Audio Recorder 20.

The Analog to Digital Audio Converter 40 is the means by which an Analog Audio File 30 is converted into a digital file format.

The Analog to Digital Audio Recorder 50 is the means by which the Analog Audio Source 10 can be recorded into a digital file format.

The Dynamic Audio File 60 (i.e. AUI, WAV, etc.) is encoded in a digital file format which contains a plurality of frequency/amplitude information by time interval and can be produced by either the Analog to Digital Audio Converter 40 or the Analog to Digital Audio Recorder 50. The Dynamic Audio File 60 is formatted in the same digital audio file format as the Dynamic Audio File 160 and 180.

The Dynamic Audio Player 70 is a means to playback a Dynamic Audio File 60.

The Frequency/Amplitude Database Compiler 80 is the means by which data contained in the Dynamic Audio File 60 is accessed and inputted into the Frequency/Amplitude Database Compiler 80 and is compiled to create the Frequency/Amplitude Database 90. The Frequency/Amplitude Database Compiler 80 is a software program, to be executed on a computer system, which can be written by one skilled in the art of audio database creation (see FIG. 12).

The Frequency/Amplitude Database 90 is the resulting digital database which is composed of three dimensions: frequency, amplitude, and time, and is produced by the Frequency/Amplitude Database Compiler 80. The Frequency/Amplitude Database 90 is a computer file which can be saved on the hard disk of a computer or saved to random access memory, or both.

The Dynamic to Static Audio Truncator 100 is the means by which repetitive data contained in the Frequency/Amplitude Database 90 is truncated to contain only the starting point of such repetition and its ending point, with respect to time, and removes any repetitive data between said starting point and said ending point and creates the Static Audio File 110. The Dynamic to Static Audio Truncator 100 is a software program, to be executed on a conventional computer system, which can be written by one skilled in the art of audio database creation (see FIG. 13).

The Static Audio File 110 is encoded in a digital file format which records a plurality of discrete frequency/amplitude information and their respective starting points and ending points, with respect to time and can be produced by the Dynamic to Static Audio Truncator 100. The Static Audio File 110 is encoded in a format which is compatible for use by the Static Audio Player 120 and/or 130, and can be saved on the hard disk of a conventional computer system. The Static Audio File 110 is formatted in the same digital audio file format as the Static Audio File 150 and 170. The Static Audio File 110 is a computer file which can be saved on the hard disk of a computer or saved to random access memory, or both.

The Static Audio File 110, 150, and/or 170 and the Static Video File 310, 350, and/or 370 may be combined into one file for use by a device which is the combination of the Static Audio Player 120 and the Static Video Player 320.

The Static Audio Player 120 is a computer software program executed by a conventional computer system. The Static Audio Player 120 is a means by which playback of the Static Audio File 110 through the sound card of the host computer system is possible in either digital audio form or analog audio form. The Static Audio Player 120 is designed to process the encoded information of the Static Audio File 110 for subsequent audio playback and/or replication. The Static Audio Player 120 invokes a sequential serial replication (i.e. a serial data replication is the process whereby the original copy of data is replicated, transmitted, and saved in series to a buffer memory) of sound information from the Static Audio File 110 and saves said sound information into a time interval buffer memory within the Static Audio Player 120. Next, the Static Audio Player 120 invokes a sequential parallel data dump of said sound information by time interval from the time interval memory buffer into a matrix of frequency/amplitude memory registers Static Audio Player 120. Next, the Static Audio Player 120 invokes a sequential parallel data replication of the sound information in the frequency/amplitude memory registers to the sound card buffer memory within the Static Audio Player 120. Next, the Static Audio Player 120 invokes a sequential parallel data dump of the sound information in the sound card buffer memory to the sound card of the host computer system, whereupon the sound card relays/transmits the sound information to the Audio Output Device 190. Each amplitude of each frequency is pre-assigned, or corresponds, to a specific frequency/amplitude memory register. The Static Audio Player 120 activates, or deactivates, the memory register corresponding to a discrete frequency/amplitude upon instruction from the Static Audio File 110 (i.e. a binary “1” activates, or is saved into, a frequency/amplitude memory register and a binary “0” deactivates, erases, or is saved into, said frequency/amplitude memory register). If the memory register of a discrete frequency/amplitude has been activated, or contains a binary “1”, then the Static Audio Player 120 will playback, and/or replicate, that frequency/amplitude until its memory register has been deactivated, erased, or contains a binary “0”. The Static Audio Player 120 may be configured to contain the functionality of the Dynamic Video Player 70, the Frequency/Amplitude Database Compiler 80, and the Dynamic to Static Audio Truncator 100.

The Static Audio Player 120 is also a means to playback a Static Audio File 110, 150, and/or 170 in dynamic digital form on a digital Audio Output Device 190 with playback output being in digital form or (i.e. digital stereo speakers, etc.); or playback in analog form on an analog Audio Output Device 190 (i.e. analog stereo speakers, etc.) for listening by the user. The Static Audio Player 120 can playback the Static Audio File 110, 150, and/or 170 in static digital form to save computational instructions as a Static Audio File 170. The Static Audio Player 120 can playback a Static Audio File 110, 150, and/or 170 in dynamic digital form to save computational instructions as a Dynamic Audio File 180.

Additionally, the Static Audio Player 120 is a means to playback a Dynamic Audio File 160 and/or 180, in dynamic digital form on an Audio Output Device 190 with playback output being in digital form or (i.e. digital stereo speakers, etc.); or playback in analog form on an Audio Output Device 190 (i.e. analog stereo speakers, etc.) for listening by the user. The Static Audio Player 120 can playback the Dynamic Audio File 160 and/or 180, in static digital form to save computational instructions as a Static Audio File 170. The Static Audio Player 120 can playback the Dynamic Audio File 160 and/or 180, in dynamic digital form to save computational instructions as a Dynamic Audio File 180.

Furthermore, the Static Audio Player 120 can receive computational instructions from a Static Audio File 150 or a Dynamic Audio File 160 (i.e. in broadcast fashion, download fashion (i.e. U.S. Pat. No. 5,191,573), etc.) by means of the Static Audio Player 130 via an Electronic Connection 140 (such as, but not limited to, transmission via: direct connect network, satellite, cable TV, coax cable, fiber optics, fiber/coax hybrid, Internet, cellular, microwave, radio, twisted pair telephone, ISDN telephone, T-1 telephone, DS-3 telephone, OC-3 telephone, etc.).

The Static Audio Player 120 and the Static Video Player 320 may be combined into one device enabling the simultaneous playback of recordings which are the combination of the Static Audio File 110, 150, and/or 170 and the Static Video File 310, 350, and/or 370.

The Static Audio Player 130 is a means by which a Static Audio File 150 and/or a Dynamic Audio File 160 may be electronically transmitted (i.e. in broadcast fashion, download fashion (i.e. U.S. Pat. No. 5,191,573), etc.) to the Static Audio Player 120 via an Electronic Connection 140 for subsequent and/or real-time playback.

The Electronic Connection 140 (such as, but not limited to, transmission via: direct connect network, satellite, cable TV, coax cable, fiber optics, fiber/coax hybrid, Internet, cellular, microwave, radio, twisted pair telephone, ISDN telephone, T-1 telephone, DS-3 telephone, OC-3 telephone, etc.) is a means by which a Static Audio Player 130 of a first computer system and a Static Audio Player 120 of a second computer system can be electronically connected. The Static Audio Player 120 and the Static Audio Player 130 may be configured to have all, or some, of the same functionality and capabilities as the other.

The Static Audio File 150 is encoded in a digital file format which records a plurality of discrete frequency/amplitude information and the respective starting points and ending points, with respect to time. The Static Audio File 150 is encoded in a format which is compatible for use by the Static Audio Player 120 and/or 130. The Static Audio File 150 is formatted in the same digital audio file format as the Static Audio File 110 and/or 170.

The Dynamic Audio File 160 (i.e. AUI, WAV, etc.) is encoded in a digital file format which contains a plurality of frequency/amplitude information by time interval. The Dynamic Audio File 160 is formatted in the same digital audio file format as the Dynamic Audio File 60 and/or 180.

The Static Audio File 170 is encoded in a digital file format which records a plurality of discrete frequency/amplitude information and the respective starting points and ending points, with respect to time and can be produced by the Static Audio Player 120. The Static Audio File 170 is encoded in a format which is compatible for use by the Static Audio Player 120 and/or 130. The Static Audio File 170 is formatted in the same digital audio file format as the Static Audio File 110 and/or 150.

The Dynamic Audio File 180 (i.e. AUI, WAV, etc.) is encoded in a digital file format which contains a plurality of frequency/amplitude information by time interval and can be produced by the Static Audio Player 120. The Dynamic Audio File 180 can be formatted in the same digital audio file format as the Dynamic Audio File 60 and/or 160.

The Audio Output Device 190 (i.e. digital and/or analog stereo speakers, etc.) is the means by which sound can be produced, in either digital or analog form, when the Static Audio File 110, 150, and/or 170 or the Dynamic Audio file 160 and/or 180 is played by means of the Static Audio Player 120. The Audio Output Device 190 is electronically connected to, and receives sound information from, a conventional computer sound card. The Audio Output Device 190 can be either a digital device or an analog device.

With respect to FIG. 1, the invention records the Analog Audio Source 10, being any form of audio source, by means of either an Analog Audio Recorder 20 or an Analog to Digital Audio Recorder 50. The Analog Audio Recorder 20 is a device which records, and/or plays, analog audio signals (i.e. cassette tape recorder/player, etc.). If the Analog Audio Recorder 20 is used, an Analog Audio File 30 is produced which is then converted into a Dynamic Audio File 60 by means of Analog to Digital Audio Converter 40. The Analog to Digital Audio Converter 40 is a device which converts analog audio signals into digital audio signals. If an Analog to Digital Audio Recorder 50 is used, a Dynamic Audio File 60 is directly produced. The Analog to Digital Audio Recorder 50 is a device which can convert analog audio signals directly into digital audio signals, can record digital audio signals, and can playback digital audio signals.

The Dynamic Audio File 60 is encoded in a format which contains a plurality of frequency/amplitude information by time interval (i.e. AUI, WAV, etc.) and can be easily edited and/or electronically manipulated. As example, and assuming that a Dynamic Audio File 60 is composed of a plurality of discrete sounds identified by their frequencies and their related amplitudes are mathematically expressed as time interval (I), frequency (F), and amplitude (A), where I_(w) identifies a discrete time interval within a range of intervals identified by subscript “w”, and bounded by the first time interval and the last time interval of the audio recording; and F_(x) identifies a discrete frequency within a range of frequencies identified by subscript “x”; and A_(y) identifies a specific amplitude, associated with said frequency F_(x), within a range of amplitudes identified by subscript “y”; and assuming the following information after the equals sign is expressed in binary terms: F₀=00000; F₁=00001; F₂=00010; F₅=00101; A₀=0000; A₁=0001; A₂=0010; and A₃=0011; where F₁A₁, F₂A₁, F₂A₂, F₅A₁, F₅A₂, and F₅A₃ represent sounds and F₀A₀ represents the lack of sound, furthermore, the Dynamic Audio File 60 mathematically represents a consecutive pattern of sound as the algorithm “I_(w)=F_(x)A_(y)”, and expressed in binary terms as: I₁=00001 0001 00010 0001 00010 0010; I₂=00001 0001 00010 0001 00010 0010; I₃=00001 0001 00010 0001 00010 0010; I₄=00001 0001 00010 0001 00010 0010 00101 0001 00101 0010 00101 0011; I₅=00001 0001 00010 0001 00010 0010 00101 0001 00101 0010 00101 0011; I₆=00001 0001 00101 0001 00101 0010 00101 0011; I₇=00001 0001 00101 0001 00101 0010 00101 0011; and I₈=00000 0000; which mathematically represents an audio recording whereby a sound F₁A₁ is to be played during time intervals I₁, I₂, I₃, I₄, I₅, I₆, and I₇; and sounds F₂A₁ and F₂A₂ are to be played during time intervals I₁, I₂, I₃, I₄, and I₅; and sounds F₅A₁, F₅A₂, and F₅A₃ are to be played during time intervals I₄, I₅, I₆, and I₇; and no sound is to be played in time interval I₈ (see FIG. 7). The data string for each time interval I_(w) is composed of pairs of groups of binary information, the first group in any pair identifies the frequency F_(x); and the second group in any pair identifies the amplitude A_(y) of said frequency F_(x). Further clarifying of this example, the “00001” in the first group of the first pair of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₁; the “0001” in the second group of the first pair of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₁ of said frequency F₁; and a specific sound F₁A₁ was consistently present in the audio recording during the time intervals from I₁ to I₇, and then the sound F₁A₁ is no longer present, or to be played, in time interval I₈. Additionally, the “00010” in the first group of the third pair of binary information in the data string associated with time intervals I₁ to I₅ identifies a discrete frequency F₂; the “0010” in the second group of the third pair of binary information in the data string associated with time intervals I₁ to I₅ identifies the specific amplitude A₂ of said frequency F₂; therefore a specific sound F₂A₂ was consistently present in the audio recording during the time intervals I₁ to I₅, and then the sound F₂A₂ is no longer present, or to be played, in time intervals I₆ to I₈. Furthermore, the “00101” in the first group of the sixth pair of binary information in the data string associated with time intervals I₄ and I₅ and the “00101” in the first group of the fourth pair of binary information in the data string associated with time intervals I₆ and I₇ identifies a discrete frequency F₅; the “0011” in the second group of the sixth pair of binary information in the data string associated with time intervals I₄ and I₅ and the “0011” in the second group of the fourth pair of binary information in the data string associated with time intervals I₆ and I₇ identifies the specific amplitude A₃ of said frequency F₅; therefore a specific sound F₅A₃ was consistently present in the audio recording during the time intervals I₄ to I₇, and then the sound F₅A₃ is no longer present, or to be played, in time interval I₈. The “00000” in the first group of the only pair of binary information in the data string associated with time interval I₈ represents the lack of a discrete frequency, or is represented as F₀; the “0000” in the second group of the only pair of binary information in the data string associated with time interval I₈ represents the lack of a specific amplitude, or is represented as A₀, of said frequency F₀; therefore F₀A₀ indicates that no sound was present in the audio recording during the time interval I₈. The Dynamic Audio File 60 records discrete frequency/amplitude information for each, and every, time interval.

Playback of the Dynamic Audio File 60 is accomplished by means of a Dynamic Audio Player 70.

The Frequency/Amplitude Database Compiler 80 is a computer software program executed by the host computer system, which inputs sound information from the Dynamic Audio File 60 into the Frequency/Amplitude Database Compiler 80 and converts the Dynamic Audio File 60 into a Frequency/Amplitude Database 90. As example, the Frequency/Amplitude Database 90 can be composed of a three-dimensional matrix defined by three axes: time interval (I), frequency (F), and amplitude (A). For each time interval I_(w) and each possible amplitude A_(y) of each possible frequency F_(x) exists a unique matrix cell f_(x)a_(y). As example, each matrix cell either has sound or lacks sound and can be mathematically expressed in binary terms by a “1” for the presence of sound or by a “0” (or no entry at all) for the lack of sound. The range of the frequency F_(x) and the range of the amplitude A_(y) and the range of time intervals I_(w) (or time intervals per second) can vary from application to application. As example, CD quality sound is generally, but not always, limited to frequencies and amplitudes which the human ear can perceive and each second of sound is divided into 44,100 discrete time intervals. The Frequency/Amplitude Database Compiler 80 accesses the sound information in the Dynamic Audio File 60 and invokes a serial data replication of said sound information to the Frequency/Amplitude Database Compiler 80 (see FIG. 12). Next, the Frequency/Amplitude Database Compiler 80 performs a sort routine with a primary sort by frequency/amplitude F_(x)A_(y) and a secondary sort by time interval I_(w) (first time interval first, last time interval last). Next, the Frequency/Amplitude Database Compiler 80 saves said sorted/collated sound information as a Frequency/Amplitude Database 90. The Frequency/Amplitude Database Compiler 80 can save the Frequency/Amplitude Database 90 on the computer hard disk of said host computer system. The Frequency/Amplitude Database Compiler 80 can electronically relay/transmit the Frequency/Amplitude Database 90 directly to the Dynamic to Static Audio Truncator 100.

Furthermore, the invention utilizes the Dynamic to Static Audio Truncator 100 which is a computer software program to be executed by the host computer system, to mathematically analyze the matrix of the Frequency/Amplitude Database and identify patterns of consecutive sound entries over time for a specific amplitude of a discrete frequency. The Dynamic to Static Audio Truncator 100 creates a Static Audio File 110. The Dynamic to Static Audio Truncator 100 accesses the sorted/collated sound information in the Frequency/Amplitude Database 90 and invokes a serial data dump/replication of said sound information to the Dynamic to Static Audio Truncator 100 (see FIG. 13). Next, the Dynamic to Static Audio Truncator 100 identifies repetition strings of frequencies/amplitudes F_(x)A_(y). Next, the Dynamic to Static Audio Truncator 100 converts the first occurrence of sound information in the repetition strings of frequencies/amplitudes F_(x)A_(y) to an “on” code (or a binary “1”) in the corresponding matrix cell f_(x)a_(y) in the corresponding time interval I_(w). Next, the Dynamic to Static Audio Truncator 100 saves an “off” code (or a binary “0”) in the time interval I_(w) immediately following the last occurrence of sound information in the repetition strings of frequencies/amplitudes F_(x)A_(y) in the corresponding matrix cell f_(x)a_(y). Next, the Dynamic to Static Audio Truncator 100 erases all occurrences of sound information related to said repetition strings of frequencies/amplitudes F_(x)A_(y) between the “on” code and the “off” code. At this point, the sound information has been truncated and the only remaining sound information with respect to said repetition strings of frequencies/amplitudes F_(x)A_(y) are “on” codes and “off” codes. Next, the Dynamic to Static Audio Truncator 100 performs a sort routine of said truncated sound information with a primary sort by time interval I_(w) (first time interval first, last time interval last) and a secondary sort by frequency/amplitude F_(x)A_(y). Next, the Dynamic to Static Audio Truncator 100 saves said sorted and truncated sound information as a Static Audio File 110. The Dynamic to Static Audio Truncator 100 can save the Static Audio File 110 on the computer hard disk of said host computer system. The Dynamic to Static Audio Truncator 100 can electronically relay/transmit the Static Audio File 110 directly to the Static Audio Player 120.

The Static Audio File 110 contains information such as, but not limited to, discrete frequencies and their related amplitudes; the related starting points when each such frequency/amplitude shall commence to be played, and/or commence to be replicated, with respect to time; and the related ending points when each such frequency/amplitude shall cease being played, and/or cease to be replicated, with respect to time. As example, and assuming that discrete sounds identified by their frequency and related amplitude are mathematically expressed as time interval (I), frequency (F), amplitude (A), time (t), and status (s), where I_(w) identifies a discrete time interval within a range of time intervals identified by the subscript “w”, which is bounded by the start time and finish time of the audio recording; and F_(x) identifies a discrete frequency within a range of frequencies identified by subscript “x”; and A_(y) identifies a specific amplitude, associated with said frequency F_(x), within a range of amplitudes identified by subscript “y”; and time t_(z) identifies a discrete moment in time within a range of time identified by the subscript “z” which is bounded by the start time and finish time of the audio recording, and t_(z) identifies when the corresponding time interval I_(w) is to commence to be played, and/or to commence to be replicated; and s_(m) identifies the status of said frequency/amplitude F_(x)A_(y) identified by subscript “m” where a “1” identifies the status of said frequency/amplitude F_(x)A_(y) as activated, and a “0” identifies the status of said frequency/amplitude F_(x)A_(y) as deactivated; and further assuming the following information after the equals sign is expressed in binary terms: F₁=00001; F₂=00010; F₅=00101; A₀=0000; A₁=0001; A₂=0010; and A₃=0011; t₁=0000001; t₂=00000100; t₃=0000011; t₄=000100; t₅=0000101; t₆=0000110; t₇=000011; t₈=0001000; s₀=0; and s₁=1; the Static Audio File 110 mathematically represents the same consecutive pattern of sound, as used in the example above for the Dynamic Audio File 60, as the algorithm “I_(w)=F_(x)A_(y)t_(z)s_(m)”, and expressed in binary terms as: I₁=00001 0001 0000001 1 00010 0001 0000001 1 00010 0010 0000001 1; I₄=00101 0001 0000100 1 00101 0010 0000100 1 00101 0011 0000100 1; I₆=00010 0001 0000110 0 00010 0010 0000110 0; and I₈=00001 0001 0001000 0 00101 0001 0001000 0 00101 0010 0001000 0 00101 0011 0001000 0; which mathematically represents an audio recording whereby a sound F₁A₁ is to be played during time intervals I₁, I₂, I₃, I₄, I₅, I₆, and I₇; and sounds F₂A₁ and F₂A₂ are to be played during time intervals I₁, I₂, I₃, I₄, and I₅; and sounds F₅A₁, F₅A₂, and F₅A₃ are to be played during time intervals I₄, I₅, I₆, and I₇; and no sound is to be played in time interval I₈ (see FIG. 9). The data string for each time interval I_(w) is composed of sets of four groups of binary information, the first group in any set identifies the frequency F_(x); the second group in any set identifies the amplitude A_(y) of said frequency F_(x); the third group in any set identifies the time t_(z) corresponding to time interval I_(w) when said frequency/amplitude F_(x)A_(y) is to commence or cease to be played, and/or replicated; and the fourth group in any set identifies the status s_(m) of the frequency/amplitude F_(x)A_(y) and contains either a binary “1” to instruct the Static Audio Player 120 to commence to play, and/or commence to replicate, said frequency/amplitude F_(x)A_(y), or a binary “0” to instruct the Static Audio Player 120 to cease to playing, and/or cease replicating, said frequency/amplitude F_(x)A_(y). In the example above, and as further clarification, the “00001” in the first group of the first set of binary information in the data string associated with time interval I₁ identifies a discrete frequency #F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₁ of said frequency F₁; the “0000001” in the third group of the first set of binary information in the data string associated with time interval I₁ identifies the time t₁ corresponding to time interval I₁ when said frequency/amplitude F₁A₁ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the first set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₁A₁ and provides the Static Audio Player 120 the instruction to commence to play, and/or commence to replicate, said frequency/amplitude F₁A₁ at time t₁ (see FIG. 3); and the “00001” in the first group of the first set of binary information in the data string associated with time interval I₈ identifies a discrete frequency F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₁ of said frequency F₁; the “0001000” in the third group of the first set of binary information in the data string associated with time interval I₈ identifies the time t₈ when said frequency/amplitude F₁A₁ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the first set of binary information in the data string associated with time interval I₈ identifies the status s₀ of said frequency/amplitude F₁A₁ and provides the Static Audio Player 120 the instruction to cease to play, and/or cease to replicate, said frequency/amplitude F₁A₁ at time interval I₈ (see FIG. 4). Additionally, the “00010” in the first group of the third set of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₂; the “0010” in the second group of the third set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₂ of said frequency F₂; the “0000001” in the third group of the third set of binary information in the data string associated with time interval I₁ identifies the time t₁ corresponding to time interval I₁ when said frequency/amplitude F₂A₂ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₂A₂ and provides the Static Audio Player 120 the instruction to commence to play, and/or commence to replicate, said frequency/amplitude F₂A₂ at time t₁; and the “00010” in the first group of the second set of binary information in the data string associated with time interval I₆ identifies a discrete frequency F₂; the “0010” in the second group of the second set of binary information in the data string associated with time interval I₆ identifies the specific amplitude A₂ of said frequency F₂; the “0000110” in the third group of the second set of binary information in the data string associated with time interval I₆ identifies the time t₆ when said frequency/amplitude F₂A₂ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the second set of binary information in the data string associated with time interval I₆ identifies the status s₀ of said frequency/amplitude F₂A₂ and provides the Static Audio Player 120 the instruction to cease to play, and/or cease to replicate, said frequency/amplitude F₂A₂ at time interval I₆, therefore a specific sound F₂A₂ was consistently present in the audio recording during the time intervals I₁ to I₅, and then the sound F₂A₂ is no longer present, or to be played, in time intervals I₆ to I₈. Furthermore, the “00101” in the first group of the sixth pair of binary information in the data string associated with time interval I₄ identifies a discrete frequency F₅; the “0011” in the second group of the sixth pair of binary information in the data string associated with time interval I₄ identifies the specific amplitude A₃ of said frequency F₅; the “0000100” in the third group of the third set of binary information in the data string associated with time interval I₄ identifies the time t₄ corresponding to time interval I₄ when said frequency/amplitude F₅A₃ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₄ identifies the status s₁ of said frequency/amplitude F₅A₃ and provides the Static Audio Player 120 the instruction to commence to play, and/or commence to replicate, said frequency/amplitude F₅A₃ at time t₄; and the “00101” in the first group of the fourth set of binary information in the data string associated with time interval I₈ identifies a discrete frequency F₅; the “0011” in the second group of the fourth set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₃ of said frequency F₅; the “0001000” in the third group of the fourth set of binary information in the data string associated with time interval I₈ identifies the time t₈ when said frequency/amplitude F₅A₃ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the fourth set of binary information in the data string associated with time interval I₈ identifies the status s₀ of said frequency/amplitude F₅A₃ and provides the Static Audio Player 120 the instruction to cease to play, and/or cease to replicate, said frequency/amplitude F₅A₃ at time interval I₈, therefore a specific sound F₅A₃ was consistently present in the audio recording during the time intervals I₄ to I₇, and then the sound F₅A₃ is no longer present, or to be played, in time interval I₈. The Static Audio File 110 is saved in the hard disk of the host computer system containing the Static Audio Player 120 and the Static Audio File 150 is saved in the hard disk of the computer system containing the Static Audio Player 130.

The Static Audio Player 120 is a computer software program saved in the hard disk of the host computer system. When the Static Audio Player 120 is activated, the central processing unit of the host computer system transmits a copy of the program to random access memory within the host computer system for execution of the various functions of the Static Audio Player 120, as is convention with most computer software programs. The Static Audio Player 120 accesses the Static Audio File 110 and replicates and saves sound information from the Static Audio File 110 into a time interval buffer memory within the Static Audio Player 120. The Static Audio Player 120 then transmits said sound information from said time interval buffer memory to the frequency/amplitude memory registers within the Static Audio Player 120, one time interval at a time. As example, the Static Audio Player 120 accesses the Static Audio File 110 and invokes a serial data replication of the sound information related to the first time interval into a frequency/amplitude matrix within a time interval buffer memory within the Static Audio Player 120. The Static Audio Player 120 then invokes a parallel data dump of said sound information related to the first time interval from said time interval buffer memory to the frequency/amplitude memory registers within the Static Audio Player 120. The Static Audio Player 120 then invokes a parallel data dump (i.e. a data dump is the process whereby data in a buffer memory is electronically transmitted to another mechanism or memory then is electronically erased from said buffer memory) of said sound information related to the first time interval from said time interval buffer memory to said frequency/amplitude memory registers. As the Static Audio Player 120 invokes a parallel data dump of said sound information related to the first time interval from said time interval buffer memory to said frequency/amplitude memory registers, the Static Audio Player 120 accesses the Static Audio File 110 and invokes a serial data replication of the sound information related to the second time interval into said frequency/amplitude memory matrix within said time interval buffer memory within the Static Audio Player 120. As the Static Audio Player 120 invokes a parallel data dump of the sound information related to the first time interval from said frequency/amplitude memory registers to a sound card buffer memory within the Static Audio Player 120 (as discussed herein below) the Static Audio Player 120 invokes a parallel data dump of said sound information related to the second time interval from said time interval buffer memory to said frequency/amplitude memory registers. The sound information in the third time interval, forth time interval, fifth time interval, etc. will continue in the above manner until the end of the Static Audio File 110.

As mentioned above, the Static Audio Player 120 saves sound information from the Static Audio File 110 into a matrix of frequency/amplitude memory registers f_(x)a_(y) within the Static Audio Player 120. Each frequency/amplitude F_(x)A_(y) is pre-assigned to a specific frequency/amplitude memory register f_(x)a_(y). The Static Audio Player 120 activates, or deactivates, the memory register f_(x)a_(y) of a discrete frequency/amplitude F_(x)A_(y) upon instruction from the Static Audio File 110. As example, a binary “1” activates, or is saved into, a frequency/amplitude memory register f_(x)a_(y) and a binary “0” deactivates, erases, or is saved into, said frequency/amplitude memory register f_(x)a_(y). It is important to note that if any of the frequency/amplitude memory registers do not receive a data dump for any particular time interval I_(w), those such frequency/amplitude memory registers f_(x)a_(y) will not be modified for any such time interval I_(w). Furthermore, once a binary “1” has been saved in a frequency/amplitude memory register f_(x)a_(y) corresponding to a frequency/amplitude F_(x)A_(y), the Static Audio Player 120 does not need to receive any further sound information from the Static Audio File 110 to enable the Static Audio Player 120 to continue to play, and/or replicate, said frequency/amplitude F_(x)A_(y) on an Audio Output Device 190. Conversely, once a binary “0” has been saved in said frequency/amplitude memory register f_(x)a_(y) corresponding to a frequency/amplitude F_(x)A_(y), or said frequency/amplitude memory register f_(x)a_(y) has been erased and/or deactivated, the Static Audio Player 120 does not need to receive any further sound information from the Static Audio File 110 to enable the Static Audio Player 120 to continue to cease play of, and/or cease replication of, said frequency/amplitude F_(x)A_(y) on an Audio Output Device 190. Using the previous example where the Static Audio File 110 mathematically represents an audio recording as the algorithm “I_(w)=F_(x)A_(y)t_(z)s_(m)”, and expressed in binary terms as: I₁=00001 0001 0000001 1 00010 0001 0000001 1 00010 0010 0000001 1; I₄=00101 0001 0000100 1 00101 0010 0000100 1 00101 0011 0000100 1; I₆=00010 0001 0000110 0 00010 0010 0000110 0; and I₈=00001 0001 0001000 0 00101 0001 0001000 0 00101 0010 0001000 0 00101 0011 0001000 0; which mathematically represents an audio recording whereby a sound F₁A₁ is to be played during time intervals I₁, I₂, I₃, I₄, I₅, I₆, and I₇; and sounds F₂A₁ and F₂A₂ are to be played during time intervals I₁, I₂, I₃, I₄, and I₅; and sounds F₅A₁, F₅A₂, and F₅A₃ are to be played during time intervals I₄, I₅, I₆, and I₇; and no sound is to be played in time interval I₈ (see FIG. 9). As further clarification, only said sounds F₁A₁, F₂A₂, and F₅A₃ are discussed below, detailing the process the Static Audio Player 120 utilizes to replicate sound information from the Static Audio File 110 to the frequency/amplitude memory registers within the Static Audio Player 120. The “00001” in the first group of the first set of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₁ of said frequency F₁; the “0000001” in the third group of the first set of binary information in the data string associated with time interval I₁ identifies the time t₁ when said frequency/amplitude F₁A₁ is to commence to be played and/or replicated; and the “1” in the fourth group of the first set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₁A₁ and upon commencing the sequential serial transmission of sound information by time interval from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₁ from the Static Audio File 110 into the time interval buffer memory, including said “1” in said fourth group of said first set of binary information in said data string associated with time interval I₁ and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₁ from the time interval buffer memory to the frequency/amplitude memory registers, including said “1” in said fourth group of said first set of binary information in said data string associated with time interval I₁ which is saved in the f₁a₁ memory register within the Static Audio Player 120 at time t₁. The “00001” in the first group of the first set of binary information in the data string associated with time interval I₈ identifies a discrete frequency F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₁ of said frequency F₁; the “0001000” in the third group of the first set of binary information in the data string associated with time interval I₈ identifies the time t₈ when said frequency/amplitude F₁A₁ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the first set of binary information in the data string associated with time interval I₈ identifies the status s_(o) of said frequency/amplitude F₁A₁ and when the sequential serial transmission of sound information by time interval reaches the point when sound information related to time interval I₈ is to be accessed from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₈ from the Static Audio File 110 into the time interval buffer memory, including said “0” in said fourth group of said first set of binary information in said data string associated with time interval I₈, and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₈ from the time interval buffer memory to the frequency/amplitude memory registers, including said “0” in said fourth group of said first set of binary information in said data string associated with time interval I₈ which is saved in the f₁a₁ memory register within the Static Audio Player 120 at time t₈. Additionally, the “00010” in the first group of the third set of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₂; the “0010” in the second group of the third set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₂ of said frequency F₂; the “0000001” in the third group of the third set of binary information in the data string associated with time interval I₁ identifies the time t₁ corresponding to time interval I₁ when said frequency/amplitude F₂A₂ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₂A₂ and upon commencing the sequential serial transmission of sound information by time interval from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₁ from the Static Audio File 110 into the time interval buffer memory, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₁, and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₁ from the time interval buffer memory to the frequency/amplitude memory registers, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₁ which is saved in the f₂a₂ memory register within the Static Audio Player 120 at time t₁. The “00010” in the first group of the second set of binary information in the data string associated with time interval I₆ identifies a discrete frequency F₂; the “0010” in the second group of the second set of binary information in the data string associated with time interval I₆ identifies the specific amplitude A₂ of said frequency F₂; the “0000110” in the third group of the second set of binary information in the data string associated with time interval I₆ identifies the time t₆ when said frequency/amplitude F₂A₂ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the second set of binary information in the data string associated with time interval I₆ identifies the status s₀ of said frequency/amplitude F₂A₂ and when the sequential serial transmission of sound information by time interval reaches the point when sound information related to time interval I₆ is to be accessed from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₆ from the Static Audio File 110 into the time interval buffer memory, including said “0” in said fourth group of said second set of binary information in said data string associated with time interval I₆, and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₆ from the time interval buffer memory to the frequency/amplitude memory registers, including said “0” in said fourth group of said second set of binary information in said data string associated with time interval I₆ which is saved in the f₂a₂ memory register within the Static Audio Player 120 at time I₆. Furthermore, the “00101” in the first group of the sixth pair of binary information in the data string associated with time interval I₄ identifies a discrete frequency F₅; the “0011” in the second group of the sixth pair of binary information in the data string associated with time interval I₄ identifies the specific amplitude A₃ of said frequency F₅; the “0000100” in the third group of the third set of binary information in the data string associated with time interval I₄ identifies the time t₄ corresponding to time interval I₄ when said frequency/amplitude F₅A₃ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₄ identifies the status s₁ of said frequency/amplitude F₅A₃ and when the sequential serial transmission of sound information by time interval reaches the point when sound information related to time interval I₄ is to be accessed from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₄ from the Static Audio File 110 into the time interval buffer memory, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₄, and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₄ from the time interval buffer memory to the frequency/amplitude memory registers, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₄ which is saved in the f₂a₂ memory register within the Static Audio Player 120 at time t₄. The “00101” in the first group of the fourth set of binary information in the data string associated with time interval I₈ identifies a discrete frequency F₅; the “0011” in the second group of the fourth set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₃ of said frequency F₅; the “0001000” in the third group of the fourth set of binary information in the data string associated with time interval I₈ identifies the time t₈ when said frequency/amplitude F₅A₃ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the fourth set of binary information in the data string associated with time interval I₈ identifies the status s₀ of said frequency/amplitude F₅A₃ and when the sequential serial transmission of sound information by time interval reaches the point when sound information related to time interval I₈ is to be accessed from the Static Audio File 110, the Static Audio Player 120 replicates and saves sound information related to time interval I₈ from the Static Audio File 110 into the time interval buffer memory, including said “0” in said fourth group of said fourth set of binary information in said data string associated with time interval I₈, and then the Static Audio Player 120 invokes a parallel data dump of all sound information related to time interval I₈ from the time interval buffer memory to the frequency/amplitude memory registers, including said “0” in said fourth group of said fourth set of binary information in said data string associated with time interval I₈ which is saved in the f₅a₃ memory register within the Static Audio Player 120 at time I₈.

Furthermore, the invention utilizes the Static Audio Player 120 to playback, and/or replicate, sound information saved from the Static Audio File 110 into the frequency/amplitude memory registers in the Static Audio Player 120. The Static Audio Player 120 sequentially replicates, one time interval at a time, the sound information contained in all of the frequency/amplitude memory registers into a sound card buffer memory within the Static Audio Player 120. Next, the Static Audio Player 120 transmits said sound information to the sound card of the host computer. Upon receipt of the sound information, said sound card transmits said sound information to the Audio Output Device 190 for playback. As example, the Static Audio Player 120 invokes a parallel data replication of the sound information related to the first time interval from the frequency/amplitude memory registers to a sound card buffer memory within the Static Audio Player 120. Next, the Static Audio Player 120 invokes a parallel data dump of the sound information related to the first time interval from the sound card buffer memory, sequentially by time interval and at the intended playback rate (i.e. 44,100 time intervals per second for CD quality sound), to said sound card through an electronic connecting bus, and said sound card transmits/relays, in either digital form or analog form, said sound information related to said first time interval to the Audio Output Device 190 for playback. While the Static Audio Player 120 invokes a parallel data replication of the sound information related to said first time interval from the frequency/amplitude memory registers to said sound card buffer memory, the Static Audio Player 120 also invokes a parallel data dump of the sound information related to the second time interval from the time interval buffer memory (as mentioned hereinabove) to said frequency/amplitude memory registers. While the Static Audio Player 120 invokes a parallel data dump of the sound information related to said first time interval from said sound card buffer memory to said sound card, the Static Audio Player 120 also invokes a parallel data replication of the sound information related to the second time interval from said frequency/amplitude memory registers to said sound card buffer memory. While said sound card transmits/relays the sound information related to said first time interval to the Audio Output Device 190 for playback, the Static Audio Player 120 invokes a parallel data dump of the sound information related to the second time interval from the sound card buffer memory to said sound card through said electronic connecting bus, and said sound card transmits/relays, in either digital form or analog form, said sound information related to said second time interval to the Audio Output Device 190 for playback. The sound information in the third time interval, forth time interval, fifth time interval, etc. will continue in the above manner until the end of the Static Audio File 110.

Additionally, the invention utilizes the Static Audio Player 120 to playback, and/or replicate, sound information saved from the Static Audio File 150 into the frequency/amplitude memory registers in the Static Audio Player 120 in a similar manner as mentioned above for the sound information received by the Static Audio Player 120 by the Static Audio File 110. The Static Audio Player 120 may receive sound information from the Static Audio File 150 via the Electronic Connection 140 in a download fashion or in a broadcast fashion. As example, in a download transmission, a Static Audio Player 130 of a sending computer system creates an electronic copy of a Static Audio File 150 and transmits said Static Audio File 150 serially by means of a conventional modem electronically connecting said sending computer system to the Electronic Connection 140 and received by a receiving computer system by means of a conventional modem electronically connecting the receiving computer system to the Electronic Connection 140 and the sound information of the Static Audio File 150 is electronically stored in the hard disk of the receiving computer system as a Static Audio File 110 (i.e. U.S. Pat. No. 5,191,573). Also as example, in a broadcast transmission, a Static Audio Player 130 of a sending computer system creates an electronic copy of a Static Audio File 150 and transmits said Static Audio File 150 serially, and at the playback rate of the recording (i.e. 44,100 time intervals per second for CD quality sound), by means of a conventional modem electronically connecting the sending computer system to the Electronic Connection 140 and received by a Static Audio Player 120 of a receiving computer system by means of a conventional modem electronically connecting said receiving computer system to the Electronic Connection 140 and the sound information of said Static Audio File 150 is subsequently transmitted by the receiving Static Audio Player 120 to the sound card of the receiving computer system for playback on the Audio Output Device 190.

The Static Audio Player 120 will playback, and/or replicate, discrete frequency/amplitude information corresponding to each memory register which is active, or contains a binary “1”. Conversely, the Static Audio Player 120 will cease playback, and/or replication, of any frequency/amplitude corresponding to any memory register which the Static Audio File 110 and/or 150 has instructed the Static Audio File 110 to deactivate, erase, or save a binary “0” within. Again, using the previous example where the Static Audio File 110 mathematically represents an audio recording as the algorithm “I_(w)=F_(x)A_(y)t_(z)s_(m)”, and expressed in binary terms as: I₁=00001 0001 0000001 1 00010 0001 0000001 1 00010 0010 0000001 1; I₄=00101 0001 0000100 1 00101 0010 0000100 1 00101 0011 0000100 1; I₆=00010 0001 0000110 0 00010 0010 0000110 0; and I₈=00001 0001 0001000 0 00101 0001 0001000 0 00101 0010 0001000 0 00101 0011 0001000 0; which mathematically represents an audio recording whereby a sound F₁A₁ is to be played during time intervals I₁, I₂, I₃, I₄, I₅, I₆, and I₇; and sounds F₂A₁ and F₂A₂ are to be played during time intervals I₁, I₂, I₃, I₄, and I₅; and sounds F₁A₁, F₅A₂, and F₅A₃ are to be played during time intervals I₄, I₅, I₆, and I₇; and no sound is to be played in time interval I₈ (see FIG. 10). As further clarification, only said sounds F₁A₁, F₂A₂, and F₅A₃ are discussed below, detailing the process the Static Audio Player 120 utilizes to play sound information from the frequency/amplitude memory registers within the Static Audio File 110 to the Audio Output Device 190. The “00001” in the first group of the first set of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₁ of said frequency F₁; the “0000001” in the third group of the first set of binary information in the data string associated with time interval I₁ identifies the time t₁ when said frequency/amplitude F₁A₁ is to be played and/or replicated; and the “1” in the fourth group of the first set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₁A₁ and enables the Static Audio Player 120 to activate, or save a binary “1” in, the f₁a₁ memory register within the Static Audio Player 120, and upon commencing the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₁ from the frequency/amplitude memory registers to the sound card buffer memory, including said “1” in said fourth group of said first set of binary information in said data string associated with time interval I₁, and then the Static Audio Player 120 invokes a sequential parallel data dump of sound information related to time interval I₁ from the sound card buffer memory to the sound card of the host computer system, including said “1” in said fourth group of said first set of binary information in said data string associated with time interval I₁, and the sound card then relays/transmits sound information related to time interval I₁ to the Audio Output Device 190, including frequency/amplitude F₁A₁ thereby enabling playback, and/or replication, of frequency/amplitude F₁A₁ at time t₁. The “00001” in the first group of the first set of binary information in the data string associated with time interval I₈ identifies a discrete frequency F₁; the “0001” in the second group of the first set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₁ of said frequency F₁; the “0001000” in the third group of the first set of binary information in the data string associated with time interval I₈ identifies the time t₈ when said frequency/amplitude F₁A₁ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the first set of binary information in the data string associated with time interval I₈ identifies the status s₀ of said frequency/amplitude F₁A₁ and enables the Static Audio Player 120 to deactivate, erase, or save a binary “0” in, the f₁a₁ memory register within the Static Audio Player 120, and when the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers reaches the point when sound information related to time interval I₈ is to be replicated from the frequency/amplitude memory registers, the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₈ from the frequency/amplitude memory registers to the sound card buffer memory, including said “0” in said fourth group of said first set of binary information in said data string associated with time interval I₈. Next, the Static Audio Player 120 invokes a sequential parallel data dump of sound information related to time interval I₈ from the sound card buffer memory to the sound card of the host computer system, including said “0” in said fourth group of said first set of binary information in said data string associated with time interval I₈, and the sound card then relays/transmits sound information related to time interval I₈ to the Audio Output Device 190, however, since said “0” in said fourth group of said first set of binary information in said data string associated with time interval I₈ is a signal to terminate playback of frequency/amplitude F₁A₁, the sound card terminates the relay/transmit of frequency/amplitude F₁A₁ to the Audio Output Device 190 thereby terminating playback, and/or replication, of frequency/amplitude F₁A₁ at time t₈. Additionally, the “00010” in the first group of the third set of binary information in the data string associated with time interval I₁ identifies a discrete frequency F₂; the “0010” in the second group of the third set of binary information in the data string associated with time interval I₁ identifies the specific amplitude A₂ of said frequency F₂; the “0000001” in the third group of the third set of binary information in the data string associated with time interval I₁ identifies the time t₁ corresponding to time interval I₁ when said frequency/amplitude F₂A₂ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₁ identifies the status s₁ of said frequency/amplitude F₂A₂ and enables the Static Audio Player 120 the activate, or save a binary “1” in, the f₂a₂ memory register within the Static Audio Player 120, and upon commencing the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₁ from the frequency/amplitude memory registers to the sound card buffer memory, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₁. Next, the Static Audio Player 120 invokes a sequential parallel data dump of all sound information related to time interval I₁ from the sound card buffer memory to the sound card of the host computer system, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₁ and the sound card then relays/transmits sound information related to time interval I₁ to the Audio Output Device 190, including frequency/amplitude F₂A₂ thereby enabling playback, and/or replication, of frequency/amplitude F₂A₂ at time t₁. The “00010” in the first group of the second set of binary information in the data string associated with time interval I₆ identifies a discrete frequency F₂; the “0010” in the second group of the second set of binary information in the data string associated with time interval I₆ identifies the specific amplitude A₂ of said frequency F₂; the “0000110” in the third group of the second set of binary information in the data string associated with time interval I₆ identifies the time t₆ when said frequency/amplitude F₂A₂ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the second set of binary information in the data string associated with time interval I₆ identifies the status s₀ of said frequency/amplitude F₂A₂ and enables the Static Audio Player 120 to deactivate, erase, or save a binary “0” in, the f₂a₂ memory register within the Static Audio Player 120, and when the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers reaches the point when sound information related to time interval I₆ is to be replicated from the frequency/amplitude memory registers, the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₆ from the frequency/amplitude memory registers to the sound card buffer memory, including said “0” in said fourth group of said second set of binary information in said data string associated with time interval I₆. Next, the Static Audio Player 120 invokes a sequential parallel data dump of all sound information related to time interval I₆ from the sound card buffer memory to the sound card of the host computer system, including said “0” in said fourth group of said second set of binary information in said data string associated with time interval I₆, and the sound card then relays/transmits sound information related to time interval I₆ to the Audio Output Device 190, however, since said “0” in said fourth group of said second set of binary information in said data string associated with time interval I₆ is a signal to terminate playback of frequency/amplitude F₂A₂, the sound card terminates the relay/transmit of frequency/amplitude F₂A₂ to the Audio Output Device 190 thereby terminating playback, and/or replication, of frequency/amplitude F₂A₂ at time t₈. Furthermore, the “00101” in the first group of the sixth pair of binary information in the data string associated with time interval I₄ identifies a discrete frequency F₅; the “0011” in the second group of the sixth pair of binary information in the data string associated with time interval I₄ identifies the specific amplitude A₃ of said frequency F₅; the “0000100” in the third group of the third set of binary information in the data string associated with time interval I₄ identifies the time t₄ corresponding to time interval I₄ when said frequency/amplitude F₅A₃ is to commence to be played, and/or to commence to be replicated; and the “1” in the fourth group of the third set of binary information in the data string associated with time interval I₄ identifies the status s₁ of said frequency/amplitude F₅A₃ and enables the Static Audio Player 120 the activate, or save a binary “1” in, the f₅a₃ memory register within the Static Audio Player 120, and when the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers reaches the point when sound information related to time interval I₄ is to be replicated from the frequency/amplitude memory registers, the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₄ from the frequency/amplitude memory registers to the sound card buffer memory, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₄. Next, the Static Audio Player 120 invokes a sequential parallel data replication of all sound information related to time interval I₄ from the sound card buffer memory to the sound card of the host computer system, including said “1” in said fourth group of said third set of binary information in said data string associated with time interval I₄, and the sound card then relays/transmits sound information related to time interval I₁ to the Audio Output Device 190, including frequency/amplitude F₅A₃ thereby enabling playback, and/or replication, of frequency/amplitude F₅A₃ at time t₄. The “00101” in the first group of the fourth set of binary information in the data string associated with time interval ˜8 identifies a discrete frequency F₅; the “0011” in the second group of the fourth set of binary information in the data string associated with time interval I₈ identifies the specific amplitude A₃ of said frequency F₅; the “0001000” in the third group of the fourth set of binary information in the data string associated with time interval ˜8 identifies the time t₈ when said frequency/amplitude F₅A₃ is to cease to be played, and/or to cease to be replicated; and the “0” in the fourth group of the fourth set of binary information in the data string associated with time interval I₈ identifies the status s₀ of said frequency/amplitude F₅A₃ and enables the Static Audio Player 120 to deactivate, erase, or save a binary “0” in, the f₅a₃ memory register within the Static Audio Player 120, and when the sequential parallel data replication of sound information by time interval from the frequency/amplitude memory registers reaches the point when sound information related to time interval I₈ is to be replicated from the frequency/amplitude memory registers, the Static Audio Player 120 invokes a sequential parallel data replication of sound information related to time interval I₈ from the frequency/amplitude memory registers to the sound card buffer memory, including said “0” in said fourth group of said fourth set of binary information in said data string associated with time interval I₈. Next, the Static Audio Player 120 invokes a sequential parallel data replication of all sound information related to time interval I₈ from the sound card buffer memory to the sound card of the host computer system, including said “0” in said fourth group of said fourth set of binary information in said data string associated with time interval I₈, and the sound card then relays/transmits sound information related to time interval I₈ to the Audio Output Device 190, however, since said “0” in said fourth group of said fourth set of binary information in said data string associated with time interval I₈ is a signal to terminate playback of frequency/amplitude F₅A₃, the sound card terminates the relay/transmit of frequency/amplitude F₅A₃ to the Audio Output Device 190 thereby terminating playback, and/or replication, of frequency/amplitude F₅A₃ at time t₈.

As discussed above, the sound information saved in the f_(x)a_(y) memory registers within in the Static Audio Player 120 can be obtained from the Static Audio File 110 one time interval at a time during real-time playback of the audio recording or the Static Audio Player 120 can obtain and schedule sound information changes for all time intervals I_(z) in the audio recording, by each frequency/amplitude FAY from the Static Audio File 110 at, or prior to, the commencement of playback of the audio recording by sequentially replicating and sequentially saving sound information related to all, or a plurality of, time intervals I_(x) from the Static Audio File 110 to the time interval buffer memory, then commencing the sequential parallel data dump from the time interval buffer memory to the frequency/amplitude memory registers. Additionally, the sound card buffer memory can be capable of sequentially storing sound information related to all, or a plurality of, time intervals I_(x) from the frequency/amplitude memory registers, prior to when the Static Audio Player 120 commences the sequential parallel data dump from the sound card buffer memory to the sound card of the host computer system for subsequent relay/transmission to the Audio Output Device 190.

Furthermore, if in an audio recording, the amplitude A_(x) of a certain frequency F_(x) is to be lowered (or deactivated) by multiple amplitude levels, from one time interval to the next, the Static Audio File 110 could be structured to contain information on only the lowest amplitude A_(x) to be deactivated. The Static Audio Player 120 could be structured to automatically deactivate (or erase) all amplitudes above said lowest amplitude A_(x) upon receipt of instructions from the Static Audio File 110 to deactivate the said lowest amplitude A_(x). As example, if the memory registers f₁a₁, f₁a₂, f₁a₃, f₁a₄, f₁a₅, f₁a₆, and f₁a₇ are active in some time interval I₁₃ and Static Audio Player 120 receives from the Static Audio File 110 the following algorithm “I₁₄=F₁A₃t₁₄s₀” expressed in binary terms as: I₁₄=00001 0011 0001110 0; then the memory registers f₁a₃, f₁a₄, f₁a₅, f₁a₆, and f₁a₇ will be deactivated, erased, or replaced with a binary “0”, and the Static Audio Player 120 will cease playing, and/or replicating, F₁A₃, F₁A₄, F₁A₅, F₁A₆, and F₁A₇ at time t₁₄, however, the Static Audio Player 120 will continue to play, and/or replicate, frequency/amplitudes F₁A₁ and F₁A₂, since memory registers f₁a₁ and f₁a₂ have not been deactivated, erased, or replaced with a binary “0”. Conversely, if in an audio recording, the amplitude A_(x) of a certain frequency F_(x) is to be increased (or activated) by multiple amplitude levels, the Static Audio File 110 could be structured to contain information on only the highest amplitude A_(x) to be activated. The Static Audio Player 120 could be structured to automatically activate all amplitudes below said highest amplitude A_(x) upon receipt of instructions from the Static Audio File 110 to activate the said highest amplitude A_(x). As example, if the frequency/amplitude memory registers f₂a₁, f₂a₂, f₂a₃, and f₂a₄ are active in some time interval I₂₆ and the Static Audio Player 120 receives from the Static Audio File 110 the following algorithm “I₂₆=F₂A₉t₂₆ m₁” expressed in binary terms as: I₂₆=00010 1001 0011010 1; then in addition to the memory registers f₂a₁, f₂a₂, f₂a₃, and f₂a₄ being active in time interval I₂₆, the Static Audio Player 120 will activate, or save a binary “1” in, the frequency/amplitude memory registers f₂a₅, f₂a₆, f₂a₇, f₂a₈, and f₂a₈, and the Static Audio Player 120 will commence playing frequency/amplitudes F₂A₅, F₂A₆, F₂A₇, F₂A₈, and F₂A₉ at time t₂₆, and the Static Audio Player 120 will continue to play frequency/amplitudes F₂A₁, F₂A₂, F₂A₃, and F₂A₄ since memory registers f₂a₁, f₂a₂, f₂a₃, and f₂a₄ continue to be active.

Additionally, the Static Audio Player 120 can be configured to contain one or more memory registers corresponding to each discrete frequency/amplitude F_(x)A_(y), in which information from the Static Audio File 110 can be saved. As example, the frequency/amplitude information may be configured to be saved in a frequency f_(x) memory register and an amplitude a_(y) memory register corresponding with frequency/amplitude F_(x)A_(y) rather than to the individual f_(x)a_(y) frequency/amplitude memory register.

Additionally, instead of the Static Audio Player 120 containing a memory register for each possible amplitude of a frequency, the Static Audio Player 120 can be configured to contain a memory register for a frequency and the corresponding binary code for the corresponding amplitude would be saved in the memory register instead of only a binary “0” or a binary “1”. By means of example, and using the previously described algorithm “I_(w)=F_(x)A_(y)t_(z)s_(m)”, the Static Audio Player 120 functions as previously described, however, the Static Audio Player 120 would contain only one frequency memory register f_(x) for each frequency F_(x) instead of plurality of frequency/amplitude memory registers f_(x)a_(y) for each such frequency F_(x); and instead of storing a binary “0” or a binary “1” in said frequency memory register f_(x), the binary code of the amplitude would be stored in said frequency memory register f_(x). Using a portion of the previously discussed example, the Static Audio File 110 expressed in binary terms as: I₁=00001 0001 0000001 1 00010 0001 0000001 1 00010 0010 0000001 1; I₄=00101 0001 0000100 1 00101 0010 0000100 1 00101 0011 0000100 1; I₆=00010 0001 0000110 0 00010 0010 0000110 0; and I₈=00001 0001 0001000 0 00101 0001 0001000 0 00101 0010 0001000 0 00101 0011 0001000 0; which mathematically represents an audio recording whereby a sound F₁A₁ is to be played during time intervals I₁, I₂, I₃, I₄, I₅, I₆, and I₇; and sounds F₂A₁ and F₂A₂ are to be played during time intervals I₁, I₂, I₃, I₄, and I₅; and sounds F₅A₁, F₅A₂, and F₅A₃ are to be played during time intervals I₄, I₅, I₆, and I₇; and no sound is to be played in time interval I₈; the second group of the any set of binary information in the data strings identifies the amplitude code to be saved in, or erased from, the corresponding frequency memory register f_(x) depending on the second group of the any set of binary information in the data strings.

Referring now to the FIG. 2, another preferred embodiment of the invention is comprised of the following:

-   -   210 Analog Video Source     -   220 Analog Video Recorder     -   230 Analog Video File     -   240 Analog to Digital Video Converter     -   250 Analog to Digital Video Recorder     -   260 Dynamic Video File     -   270 Dynamic Video Player     -   280 Frequency/Amplitude Database Compiler     -   290 Frequency/Amplitude Database     -   300 Dynamic to Static Video Truncator     -   310 Static Video File     -   320 Static Video Player     -   330 Static Video Player     -   340 Electronic Connection     -   350 Static Video File     -   360 Dynamic Video File     -   370 Static Video File     -   380 Dynamic Video File     -   390 Video Output Device

In FIG. 2, the following components are already commercially available: the Analog Video Source 210; the Analog Video Recorder 220; the Analog Video File 230; the Analog to Digital Video Converter 240; the Analog to Digital Video Recorder 250; the Dynamic Video File 260, 360, and 380; the Dynamic Video Player 270; the Electronic Connection 340; and the Video Output Device 390. However, the Red/Green/Blue Database Compiler 280; the Red/Green/Blue Database 290; the Dynamic to Static Video Truncator 300; the Static Video File 310, 350, and 370; and the Static Video Player 320 and 330; would be designed specifically to meet the teachings of this invention.

The Analog Video Source 210 is the originating source of a video recording in the configuration as outlined in FIG. 2.

The Analog Video Recorder 220 (i.e. VHS Video Cassette Recorder, BETA Video Cassette Recorder, etc.) is the means by which the Analog Video Source 210 can be recorded in either analog form or digital form.

The Analog Video File 230 is the resulting analog video file produced by the Analog Video Recorder 220.

The Analog to Digital Video Converter 240 is the means by which an Analog Video File 230 is converted into a digital video file format.

The Analog to Digital Video Recorder 250 is the means by which the Analog Video Source 210 can be recorded directly into a digital video file format.

The Dynamic Video File 260 (i.e. MPEG, etc.) is encoded in a dynamic digital file format which contains basic, and/or complex, color information by pixel by video frame and can be produced by either the Analog to Digital Video Converter 240 or the Analog to Digital Video Recorder 250. The Dynamic Video File 260 is formatted in the same dynamic digital video file format as the Dynamic Video File 360 and 380.

The Dynamic Video Player 270 is a means to playback a Dynamic Video File 260.

The Red/Green/Blue Database Compiler 280 is the means by which data contained in the Dynamic Video File 260 is accessed and inputted into the Red/Green/Blue Database Compiler 280 and is compiled to create the Red/Green/Blue Database 290. The Red/Green/Blue Database Compiler 280 is a computer software program, to be executed on a computer system, which can be written by one skilled in the art of video database creation (see FIG. 14).

The Red/Green/Blue Database 290 is composed of a plurality of video frames composed of a matrix of pixels, each pixel contains data representing a specific complex color which may be defined by various shades of the basic colors red, green, and blue.

The Dynamic to Static Video Truncator 300 is the means by which repetitive data contained in the Red/Green/Blue Database 290 is truncated to contain specific color information by pixel and the related the starting points each such color is to commence to be displayed, and/or commence to be replicated, within each such pixel, with respect to time, and removes any repetitive data between said starting point and said ending point and creates the Static Video File 310. The Dynamic to Static Video Truncator 300 is a computer software program, to be executed on a conventional computer system, which can be written by one skilled in the art of video database creation (see FIG. 15).

The Static Video File 310 is encoded in a digital file format which records basic color information of the red/green/blue components of specific complex colors to be displayed, and/or replicated, within discrete pixels on a Video Output Device 390 and the related starting points each such specific complex color is to commence to be displayed, and/or commence to be replicated, within each such pixel, for one or more consecutive video frames, with respect to time and can be produced by the Dynamic to Static Video Truncator 300. The Static Video File 310 is encoded in a format which is compatible for use by the Static Video Player 320 and 330, and can be saved on the hard disk of a conventional computer system. The Static Video File 310 is formatted in the same digital video file format as the Static Video File 350 and 370.

The Static Video File 310 and the Static Audio File 110 may be combined into one file for use by a device which is the combination of the Static Video Player 320 and the Static Audio Player 120.

The Static Video Player 320 is a computer software program executed by a conventional computer system. The Static Video Player 320 is a means by which display of the Static Video File 310 through the video card of the host computer system is possible in either digital audio form or analog audio form. The Static Video Player 320 is designed to process the encoded information of the Static Video File 310 for subsequent video display and/or replication. The Static Video Player 320 invokes a sequential serial replication (i.e. a serial data replication is the process whereby the original copy of data is replicated, transmitted, and saved in series to a buffer memory) of color information from the Static Video File 310 and saves said color information into a video frame buffer memory within the Static Video Player 320. Next, the Static Video Player 320 invokes a sequential parallel data dump of said color information by video frame from the video frame memory buffer into a matrix of red/green/blue memory registers within the Static Video Player 320. Next, the Static Video Player 320 invokes a sequential parallel data replication of the color information in the red/green/blue memory registers to the video card buffer memory within the Static Video Player 320. Next, the Static Video Player 320 invokes a sequential parallel data dump of the color information in the video card buffer memory to the video card of the host computer system, whereupon the video card relays/transmits the color information to the Video Output Device 390. Each red/green/blue memory register is pre-assigned, or corresponds, to a specific pixel on a Video Output Device 390. The Static Video Player 320 saves red/green/blue color information from the Static Video File 310 into corresponding red/green/blue memory registers. The Static Video Player 320 generates complex colors from the red/green/blue color information. The Static Video Player 320 displays complex colors, generated from the red/green/blue color information saved in the red/green/blue memory registers, within the corresponding pixels on a Video Output Device 390. As the color information saved in the red/green/blue memory registers changes from video frame to video frame, the complex color displayed within the corresponding pixels on a Video Output Device 390 changes accordingly. The Static Video Player 320 may be configured to contain the functionality of the Dynamic Video Player 270, the Red/Green/Blue Database Compiler 280, and the Dynamic to Static Video Truncator 300.

The Static Video Player 320 is also a means to playback the Static Video File 310, 350, and/or 370 in dynamic digital form on a Video Output Device 390 (i.e. digital video monitor, digital television set, etc.); or playback in analog form on a Video Output Device 390 (i.e. analog video monitor, analog television set, etc.) for view by the user. The Static Video Player 320 can playback the Static Video File 310, 350, and/or 370 in static digital form to save computational instructions as a Static Video File 370. The Static Video Player 320 can playback the Static Video File 310, 350, and/or 370 in dynamic digital form to save computational instructions as a Dynamic Video File 380.

Additionally, the Static Video Player 320 is a means to playback the Dynamic Video File 360 and/or 380 in dynamic digital form on a Video Output Device 390 (i.e. digital video monitor, digital television set, etc.); or playback in analog form on a Video Output Device 390 (i.e. analog video monitor, analog television set, etc.) for view by the user. The Static Video Player 320 can playback the Dynamic Video File 360 and/or 380 in static digital form to save computational instructions as a Static Video File 370. The Static Video Player 320 can playback the Dynamic Video File 360 and/or 380 in dynamic digital form to save computational instructions as a Dynamic Video File 380.

Furthermore, the Static Video Player 320 can receive computational instructions from a Static Video File 350 or a Dynamic Video File 360 (i.e. in broadcast fashion, download fashion (i.e. U.S. Pat. No. 5,191,573), etc.) by means of the Static Video Player 330 via an Electronic Connection 340 (such as, but not limited to, transmission via: direct connect network, satellite, cable TV, coax cable, fiber optics, fiber/coax hybrid, Internet, cellular, microwave, radio, twisted pair telephone, ISDN telephone, T-1 telephone, DS-3 telephone, OC-3 telephone, etc.).

The Static Video Player 320 and the Static Audio Player 120 may be combined into one device enabling the simultaneous playback of recordings which are the combination of the Static Video File 310 and the Static Audio File 110.

The Static Video Player 330 is a means by which a Static Video File 350 and/or a Dynamic Video File 360 may be electronically transmitting (i.e. in broadcast fashion, download fashion (i.e. U.S. Pat. No. 5,191,573), etc.) to a Static Video Player 320 via an Electronic Connection 340 for subsequent or real-time playback by the Static Video Player 320.

The Electronic Connection 340 (such as, but not limited to, transmission via: direct connect network, satellite, cable TV, coax cable, fiber optics, fiber/coax hybrid, Internet, cellular, microwave, radio, twisted pair telephone, ISDN telephone, T-1 telephone, DS-3 telephone, OC-3 telephone, etc.) is a means by which a Static Video Player 330 of a first computer system and a Static Video Player 320 of a second computer system can be electronically connected. The Static Video Player 320 and the Static Video Player 330 may be configured to have all, or some, of the same functionality and capabilities as the other.

The Static Video File 350 is encoded in a digital file format which records basic color information of the red/green/blue components of specific complex colors to be displayed, and/or replicated, within discrete pixels on a Video Output Device 390 and the related starting points each such complex color is to commence to be displayed, and/or commence to be replicated, within each such pixel for one or more consecutive video frames, with respect to time. The Static Video File 350 is formatted in the same digital video file format as the Static Video File 310 and 370.

The Dynamic Video File 360 (i.e. MPEG, etc.) is encoded in a file format which contains basic color, and/or complex color, information by pixel by video frame. The Dynamic Video File 360 is formatted in the same digital video file format as the Dynamic Video File 260 and 380.

The Static Video File 370 is encoded in a digital file format which records basic color information of the red/green/blue components of specific complex colors to be displayed, and/or replicated, within discrete pixels on a Video Output Device 390 and the related starting points each such complex color is to commence to be displayed, and/or commence to be replicated, within each such pixel, for one or more consecutive video frames, with respect to time and can be produced by the Static Video Player 310. The Static Video File 370 is formatted in the same digital video file format as the Static Video File 310 and 350.

The Dynamic Video File 380 (i.e. MPEG, etc.) is encoded in a digital file format which contains basic color, and/or complex color, information by pixel by video frame and can be produced by the Static Video Player 320. The Dynamic Video File 380 is formatted in the same digital video file format as the Dynamic Video File 260 and 360.

The Video Output Device 390 (i.e. computer monitor, television set, video monitor, etc.) is the means by which an image is produced, in either digital or analog form, for view when the Static Video File 310, 350, and/or 370 or the Dynamic File 360 and/or 380 is played by means of the Static Video Player 320. The Video Output Device 390 is electronically connected to, and receives color information by pixel from, a computer video card. The Video Output Device 390 can be either a digital device or an analog device.

With respect to FIG. 2, the invention records an Analog Video Source 210, being any form of a video recording, through use of the Analog Video Recorder 220, which is a device which records, and/or plays, analog video signals (i.e. VHS Video Cassette Recorder, BETA Video Cassette Recorder, etc.), or through use of the Analog to Digital Video Recorder 250. The Analog to Digital Video Recorder 250 is a device which can convert analog video signals directly into digital video signals, can record digital video signals, and which can playback digital video signals. If the Analog Video Recorder 220 is utilized, an Analog Video File 230 is created. The Analog to Digital Video Converter 240, a device which converts analog video signals into digital video signals, creates a Dynamic Video File 260 from the Analog Video File 230.

The Dynamic Video File 260 is created in a dynamic digital video file format (i.e. MPEG). If the Analog to Digital Video Recorder 250 is used, the Dynamic Video File 260 is directly created. As example, and assuming that a Dynamic Video File 260 is composed a plurality of video frames (F), where F_(w) identifies a discrete video frame within a range of sequentially positioned video frames identified by subscript “w” which is bounded by the first video frame and last video frame of the video recording; and each such video frame F_(w) is composed of discrete pixels which are mathematically expressed as, and/or are located by, height (h) and length (l), where (h) is a vertical Euclidean axis at right angle to (l), which is a horizontal Euclidean axis, and h_(x) identifies a discrete location along the (h) axis within a range of locations identified by subscript “x”, and l_(y) identifies a discrete location along the (l) axis within a range of locations identified by subscript “y”, and the intersection of h_(x) and l_(y) identifies a discrete video location, known as a pixel h_(x)l_(y), within the area bounded by the (h) axis and the (l) axis; and complex colors are composed of a mixture of the basic colors red (R), green (G), and blue (B), where R_(v)G_(v)B_(v) identifies discrete shades of red, green, and blue, respectively, within a range of shades from 0 to 255 identified by subscript “v”; and further assuming that the following information after the equals sign is expressed in binary terms: h₁=00001; h₄=00100; h₁=01011; l₁=00001; l₇=00111; l₂₀=10100; R₀₀₀=00000000; R₀₇₄=01001010; R₁₁₆=01110100; R₁₄₂=10001110; R₂₃₃=11101001; G₀₀₀=00000000; G₁₄₀=10001100; G₁₉₅=11000011; G₂₂₈=11100100; G₂₅₅=11111111; B₀₀₀=00000000; B₀₉₅=01011111; B₁₁₈=01110110; and B₂₃₂=11101000; the Dynamic Video File 260 mathematically represents a video recording as the algorithm “F_(w)=h_(z)l_(y)R_(v)G_(v)B_(v)”, and expressed in binary terms as: F₁=00001 00001 01110100 00000000 01011111 00100 00111 01001010 11111111 00000000 01011 10100 11101001 11100100 00000000; F₂=00001 00001 01110100 00000000 01011111 00100 00111 01001010 11111111 00000000 01011 10100 11101001 11100100 00000000; F₃=00001 00001 01110100 00000000 01011111 00100 00111 01001010 11111111 00000000 01011 10100 11101001 11100100 00000000; F₄=00001 00001 01110100 00000000 01011111 00100 00111 01001010 11111111 00000000 01011 10100 11101001 11100100 00000000; F₅=00001 00001 01110100 00000000 01011111 00100 00111 01001010 11111111 00000000 01011 10100 11101001 11100100 00000000; F₆=00001 00001 01110100 00000000 01011111 00100 00111 10001110 11000011 11101000 01011 10100 11101001 11100100 00000000; F₇=00001 00001 01110100 00000000 01011111 00100 00111 10001110 11000011 11101000 01011 10100 11101001 11100100 00000000; and F₈=00001 00001 00000000 10001100 01110110 00100 00111 10001110 11000011 11101000 01011 10100 11101001 11100100 00000000; which mathematically represents a video recording whereby a shade of purple (R₁₁₆G₀₀₀B₀₉₅) is to be displayed within pixel h₁l₁ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, and F₇, then in video frame F₈ a shade of teal (R₀₀₀G₁₄₀B₁₁₈) is to be displayed within pixel h₁l₁; a shade of lime green (R₀₇₄G₂₅₅B₀₀₀) is to be displayed within pixel h₄₁₇ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, and F₅, then in video frames F₆, F₇, and F₈ a shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) is to be displayed within pixel h₄₁₇; and a shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) is to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ (see FIG. 16). The data string for each video frame F_(w) is composed of sets of five groups of binary information, each set contains binary information for a pixel h_(x)l_(y), the first and second groups of binary information in a set identify a pixel h_(x)l_(y), the third group of binary information in a set identifies red color information R_(v), the fourth group of binary information in a set identifies green color information G_(v), and the fifth group of binary information in a set identifies blue color information B_(v). The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₁ identify the pixel h₁l₁; the “01110100 00000000 01011111” in the third, fourth, and fifth groups of the first set of binary information in the data strings associated with video frames F₁, F₂, F₃, F₄, F₅, F₆, and F₇ identify a shade of purple, being a complex color generated by the mixture of the basic colors R₁₁₆G₀₀₀B₀₉₅, to be displayed within pixel h₁l₁ on a Video Output Device 390. The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₈ identify the pixel h₁l₁; the “00000000 10001100 01110110” in the third, fourth, and fifth groups of the first set of binary information in the data string associated with video frame F₈ identify a shade of teal, being a complex color generated by the mixture of the basic colors R₀₀₀G₁₄₀B₁₁₈, to be displayed within pixel h₁l₁ on a Video Output Device 390. The “00100 00111” in the first and second groups of the second set of binary information in the data string associated with video frames F₁, F₂, F₃, F₄, and F₅ identify the pixel h₄l₇; the “01001010 11111111 00000000” in the third, fourth, and fifth groups of the second set of binary information in the data strings associated with video frames F₁, F₂, F₃, F₄, and F₅ identify a shade of lime green, being a complex color generated by the mixture of the basic colors R₀₇₄G₂₅₅B₀₀₀, to be displayed within pixel h₄l₇ on a Video Output Device 390. The “00100 00111” in the first and second groups of the second set of binary information in the data string associated with video frames F₆, F₇, and F₈ identify the pixel h₄l₇; the “10001110 11000011 11101000” in the third, fourth, and fifth groups of the second set of binary information in the data string associated with video frames F₆, F₇, and F₈ identify a shade of powder blue, being a complex color generated by the mixture of the basic colors R₁₄₂G₁₉₅B₂₃₂, to be displayed within pixel h₄l₇ on a Video Output Device 390. The “01011 10100” in the first and second groups of the third set of binary information in the data string associated with video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ identify the pixel h₁₁l₂₀; the “11101001 11100100 00000000” in the third, fourth, and fifth groups of the third set of binary information in the data strings associated with video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ identify a shade of lemon yellow, being a complex color generated by the mixture of the basic colors R₂₃₃G₂₂₈B₀₀₀, to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390. The Dynamic Video File 260 records color information to be displayed in each pixel of a Video Output Device 390 for each, and every, video frame.

Playback of the Dynamic Video File 260 is accomplished by means of a Dynamic Video Player 270, which is a device which can play the Dynamic Video File 260. The Dynamic Video Player 270 receives color information from the Dynamic Video File 260 for playback one video frame at a time (see FIG. 17).

The Red/Green/Blue Database Compiler 280 is a computer software program to be executed by the host computer system, which inputs color information from a Dynamic Video File 260 into the Red/Green/Blue Database Compiler 280 and creates a Red/Green/Blue Database 290. As example, the Red/Green/Blue Database 290 can be composed of a three-dimensional matrix defined by three axes, video frame (F), video frame height (h), and video frame length (l). A video frame F_(w), where subscript “w” represents the range of video frames bounded by the first video frame and the last video frame of the video recording, is composed of a plurality of discrete pixels. The location of each such pixel h_(x)l_(y) can be determined using a typical Euclidean coordinate system with video frame height (h) at right angle to video frame length (l), where subscript “x” represents the relative position along the (h) axis, and subscript “y” represents the relative position along the (l) axis. Each pixel contains a complex color composed of a mixture of the basic colors red (R), green (G), and blue (B), where R_(v)G_(v)B_(v) identifies discrete shades of red, green, and blue respectively, within a range of shades identified by subscript “v”. As example, white, being a complex color can be mathematically expressed as the mixture of the basic colors R₂₅₅G₂₅₅B₂₅₅, and black, being a complex color can be mathematically expressed as the mixture of the basic colors R₀₀₀G₀₀₀B₀₀₀, where the total possible shades identified by subscript “v” range from 000 to 255. These shades of basic colors, could be represented in binary terms as: 000=00000000; 001=00000001; 002=00000010; . . . 040=00101000; and so forth with 255=11111111. Therefore, a shade of purple, being a complex color can be mathematically expressed as the mixture of the basic colors R₁₁₆G₀₀₀B₀₀₅ is expressed in binary terms as “01110100 00000000 01011111” where R₁₁₆=01110100, G₀₀₀=0000000, and B₀₉₅=01011111. The number of shades of the basic colors red, green, and blue, and the number of video frames per second, and the number of pixels per video frame can vary from application to application. The Red/Green/Blue Database Compiler 280 accesses the color information in the Dynamic Video File 260 and invokes a serial data replication of said color information to the Red/Green/Blue Database Compiler 280 (see FIG. 14). Next, the Red/Green/Blue Database Compiler 280 performs a sort routine with a primary sort by pixel h_(x)l_(y) and a secondary sort by video frame F_(w) (first video frame first, last video frame last). Next, the Red/Green/Blue Database Compiler 280 saves said sorted/collated color information as a Red/Green/Blue Database 290. The Red/Green/Blue Database Compiler 280 can save the Red/Green/Blue Database 290 on the computer hard disk of said host computer system. The Red/Green/Blue Database Compiler 280 can electronically relay/transmit the Red/Green/Blue Database 290 directly to the Dynamic to Static Video Truncator 300.

Furthermore, the invention utilizes the Dynamic to Static Video Truncator 300, which is a computer software program to be executed by the host computer system, to mathematically analyze the matrix of the Red/Green/Blue Database 290 and identify patterns of specific complex colors, and/or basic colors, to be displayed, and/or replicated, within discrete pixels for one or more consecutive video frames, and records only the start point and finish point of any consecutive repetitions of color information corresponding to any pixel h_(x)l_(y), with respect to time, and the Dynamic to Static Video Truncator 300 saves such truncated information in a Static Video File 310. The Dynamic to Static Video Truncator 300 accesses the sorted/collated color information in the Red/Green/Blue Database 290 and invokes a serial data dump/replication of said color information to the Dynamic to Static Video Truncator 300 (see FIG. 15). Next, the Dynamic to Static Video Truncator 300 identifies repetition strings of identical color information in pixels h_(x)l_(y) over video frames F_(w). Next, the Dynamic to Static Video Truncator 300 erases the second occurrence and all subsequent occurrences of color information in the repetition strings related to the corresponding pixels h_(x)l_(y) over the corresponding video frames F_(w). At this point, the color information has been truncated and the only remaining color information with respect to said repetition strings of identical color information in pixels h_(x)l_(y) over video frames F_(w) are the starting points of said repetition strings. Next, the Dynamic to Static Video Truncator 300 performs a sort routine of said truncated color information with a primary sort by video frame F_(w) (first video frame first, last video frame last) and a secondary sort by pixels h_(x)l_(y). Next, the Dynamic to Static Video Truncator 300 saves said sorted and truncated color information as a Static Video File 310. The Dynamic to Static Video Truncator 300 can save the Static Video File 310 on the computer hard disk of said host computer system. The Dynamic to Static Video Truncator 300 can electronically relay/transmit the Static Video File 310 directly to the Static Video Player 320.

The Static Video File 310 contains information such as, but not limited to, specific complex and/or basic colors to be displayed, and/or replicated, within discrete pixels on a Video Output Device 390 and the related starting points each such complex color is, and/or basic colors are, to be displayed, and/or replicated, within each such pixel for one or more consecutive video frames, with respect to time. As example, and assuming that a Static Video File 310 is composed a plurality of video frames (F), where F_(w) identifies a discrete video frame within a range of sequential video frames identified by subscript “w”, and bounded by the first video frame and last video frame of the video recording; and each such video frame F_(w) is composed of discrete pixels which are mathematically expressed as, and/or located by, height (h) and length (l), where (h) is a vertical Euclidean axis at right angle to (l), which is a horizontal Euclidean axis, and h_(x) identifies a discrete location along the (h) axis within a range of locations identified by subscript “x”, and l_(y) identifies a discrete location along the (l) axis within a range of locations identified by subscript “y”, and the intersection of h_(x) and l_(y) identifies a discrete location, or pixel h_(x)l_(y), within the area bounded by the (h) axis and the (l) axis of the Video Output Device 390; and complex colors are composed a mixture of the basic colors red (R), green (G), and blue (B), where R_(v)G_(v)B_(v), where subscript “v” identify discrete shades of red, green, and blue, respectively, within a range of shades from 0 to 255; and time t_(z) identifies a discrete moment in time within a range of time identified by the subscript “z” which is bounded by the start time and finish time of the video recording, and t_(z) identifies when the basic colors R_(v)G_(v)B_(v) corresponding to video frame F_(w) are to commence to be displayed, and/or commence to be replicated, within pixel h_(x)l_(y) on a Video Output Device 390; and further assuming the following information after the equals sign is expressed in binary terms: h₁=00001; h₄=00100; h₁₁=01011; l₁=00001; l₇=00111; l₂₀=10100; R₀₀₀=00000000; R₀₇₄=01001010; R₁₁₆=01110100; R₁₄₂=10001110; R₂₃₃=11101001; G₀₀₀=0000000; G₁₄₀=10001100; G₁₉₅=11000011; G₂₂₈=11100100; G₂₅₅=11111111; B₀₀₀=00000000; B₀₉₅=01011111; B₁₁₈=01110110; and B₂₃₂=11101000; t₁=0000001; t₂=0000010; t₃=0000011; t₄=0000100; t₅=0000101; t₆=0000110; t₇=0000111; and t₈=0001000; the Static Video File 310 mathematically represents the same video recording as used in the previous example for the Dynamic Video File 260, as the algorithm “F_(w)=h_(x)l_(y)R_(v)G_(v)B_(v)t_(z)” and expressed in binary terms as: F₁=00001 00001 01110100 00000000 01011111 0000001 00100 00111 01001010 11111111 00000000 0000001 01011 10100 11101001 11100100 00000000 0000001; F₆=00100 00111 10001110 11000011 11101000 0000110; F₈=00001 00001 00000000 10001100 01110110 0001000; which mathematically represents a video recording whereby a shade of purple (R₁₁₆G₀₀₀B₀₉₅) is to be displayed within pixel h₁l₁ of a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, and F₇, then in video frame F₈ a shade of teal (R₀₀₀G₁₄₀B₁₁₈) is to be displayed within pixel h₁l₁; a shade of lime green (R₀₇₄G₂₅₅B₀₀₀) is to be displayed within pixel h₄₁₇ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, and F₅, then in video frames F₆, F₇, and F₈ a shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) is to be displayed within pixel h₄₁₇; and a shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) is to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ (see FIG. 18). The data string for each video frame F_(w) is composed of sets of six groups of binary information, the first and second groups of binary information in a set identify a pixel h_(x)l_(y), the third group of binary information in a set identifies red color information R_(v), the fourth group of binary information in a set identifies green color information G_(v), the fifth group of binary information in a set identifies blue color information B_(v), and the sixth group of binary information in a set identifies a discrete time t_(z). The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₁ identify pixel h₁l₁; the “01110100 00000000 01011111” in the third, fourth, and fifth groups of the first set of binary information in the data string associated with video frame F₁ identify a shade of purple, being a complex color generated by the mixture of the basic colors R₁₁₆G₀₀₀B₀₉₅; and the “0000001” in the sixth group of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to commence to display said shade of purple (R₁₁₆G₀₀₀B₀₉₅) within pixel h₁l₁ on a Video Output Device 390 and continue to replicate said shade of purple (R₁₁₆G₀₀₀B₀₉₅) within pixel h₁l₁ on a Video Output Device 390 during all subsequent video frames until instructed otherwise, and in this example those video frames are F₂, F₃, F₄, F₅, F₆, and F₇, (see FIG. 5). The “00001 00001” in the first and second groups of the only set of binary information in the data string associated with video frame F₈ identify pixel h₁l₁; the “00000000 10001100 01110110” in the third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₈ identify a shade of teal, being a complex color generated by the mixture of the basic colors R₀₀₀G₁₄₀B₁₁₈; and the “0001000” the sixth group of the only set of binary information in the data string associated with video frame F₈ identifies the time t₈ when the Static Video Player 320 is to commence to display said shade of teal (R₀₀₀G₁₄₀B₁₁₈) within pixel h₁l₁ on a Video Output Device 390 (see FIG. 6). The “00100 00111” in the first and second groups of the second set of binary information in the data string associated with video frame F₁ identify pixel h₄l₇; the “01001010 11111111 00000000” in the third, fourth, and fifth groups of the second set of binary information in the data string associated with video frame F₁ identify a shade of lime green, being a complex color generated by the mixture of the basic colors R₀₇₄G₂₅₅B₀₀₀; and the “0000001” in the sixth group of the second set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to commence to display said shade of lime green (R₀₇₄G₂₅₅B₀₀₀) within pixel h₄l₇ on a Video Output Device 390 and continue to replicate said shade of lime green (R₀₇₄G₂₅₅B₀₀₀) within pixel h₄l₇ on a Video Output Device 390 during all subsequent video frames until instructed otherwise, and in this example those video frames are F₂, F₃, F₄, and F₅. The “00100 00111” in the first and second groups of the only set of binary information in the data string associated with video frame F₆ identify pixel h₄l₇; the “10001110 11000011 11101000” in the third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₆ identify a shade of powder blue, being a complex color generated by the mixture of the basic colors R₁₄₂G₁₉₅B₂₃₂; and the “0000110” the sixth group of the only set of binary information in the data string associated with video frame F₆ identifies the time t₆ when the Static Video Player 320 is to commence to display said shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) within pixel h₄l₇ on a Video Output Device 390 and continue to replicate said shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) within pixel h₄l₇ on a Video Output Device 390 during all subsequent video frames until instructed otherwise, and in this example those video frames are F₇ and F₈. The “01011 10100” in the first and second groups of the third set of binary information in the data string associated with video frame F₁ identify pixel h₁₁l₂₀; the “11101001 11100100 00000000” in the third, fourth, and fifth groups of the third set of binary information in the data string associated with video frame F₁ identify a shade of lemon yellow, being a complex color generated by the mixture of the basic colors R₂₃₃G₂₂₈B₀₀₀; and the “0000001” in the sixth group of the third set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to commence to display said shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) within pixel h₁₁l₂₀ on a Video Output Device 390 and continue to replicate said shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) within pixel h₁₁l₂₀ on a Video Output Device 390 during all subsequent video frames until instructed otherwise, and in this example those video frames are F₂, F₃, F₄, F₅, F₆, F₇, and F₈. The Static Video File 310 is saved in the hard disk of the host computer system containing the Static Video Player 320 and the Static Video File 350 is saved in the hard disk of the computer system containing the Static Video Player 330.

The Static Video Player 320 is a computer software program saved in the hard disk of the host computer system. When the Static Video Player 320 is activated, the central processing unit of the host computer system transmits a copy of the program to random access memory within the host computer system for execution of the various functions of the Static Video Player 320, as is convention with most computer software programs. The Static Video Player 320 accesses the Static Video File 310 and replicates and saves color information from the Static Video File 310 into a video frame buffer memory within the Static Video Player 320. The Static Video Player 320 then transmits said color information from said video frame buffer memory to the red/green/blue memory registers within the Static Video Player 320, one video frame at a time. As example, the Static Video Player 320 accesses the Static Video File 310 and invokes a serial data replication of the color information related to the first video frame into a red/green/blue matrix within a video frame buffer memory within the Static Video Player 320. The Static Video Player 320 then invokes a parallel data dump (i.e. a data dump is the process whereby data in a buffer memory is electronically transmitted to another mechanism or memory then is electronically erased from said buffer memory) of said color information related to the first video frame from said video frame buffer memory to the red/green/blue memory registers within the Static Video Player 320. The Static Video Player 320 then invokes a parallel data dump of said color information related to the first video frame from said video frame buffer memory to said red/green/blue memory registers. As the Static Video Player 320 invokes a parallel data dump of said color information related to the first video frame from said video frame buffer memory to said red/green/blue memory registers, the Static Video Player 320 accesses the Static Video File 310 and invokes a serial data replication of the color information related to the second video frame into said red/green/blue memory matrix within said video frame buffer memory within the Static Video Player 320. As the Static Video Player 320 invokes a parallel data dump of the color information related to the first video frame from said red/green/blue memory registers to a video card buffer memory within the Static Video Player 320 (as discussed herein below) the Static Video Player 320 invokes a parallel data dump of said color information related to the second video frame from said video frame buffer memory to said red/green/blue memory registers. The color information in the third video frame, forth video frame, fifth video frame, etc. will continue in the above manner until the end of the Static Video File 310.

As mentioned above, the Static Video Player 320 saves color information from the Static Video File 310 into a matrix video memory registers r_(x/y)g_(x/y)b_(x/y) within the Static Video Player 320, where r_(x/y) represents memory registers for the basic color red, g_(x/y) represents memory registers for the basic color green, and b_(x/y) represents memory registers for the basic color blue. The video memory registers r_(x/y)g_(x/y)b_(x/y) correspond to each such previously defined pixel h_(x)l_(y), and subscript “x/y” of said memory registers corresponds to the subscripts “x” and “y” of each such pixel h_(x)l_(y). It is important to note that if any of the video memory registers r_(x/y)g_(x/y)b_(x/y) do not receive a data dump for any particular video frame F_(w), those such video memory registers r_(x/y)g_(x/y)b_(x/y) will not be modified for any such video frame F_(w). Furthermore, once a specific color R_(v)G_(v)B_(v) has been saved in a memory register r_(x/y)g_(x/y)b_(x/y), corresponding to a pixel h_(x)l_(y) of a Video Output Device 390, the Static Video Player 320 does not need to receive any further color information from the Static Video File 310 to enable the Static Video Player 320 to continue to display, and/or replicate, said specific color R_(v)G_(v)B_(v) within said pixel h_(x)l_(y) of a Video Output Device 390. The Static Video Player 320 saves the R_(v)G_(v)B_(v) color information from the Static Video File 310 into the corresponding video memory registers r_(x/y)g_(x/y)b_(x/y), with respect to time, and corresponding to pixel h_(x)l_(y) of a Video Output Device 390. Using the previous example where the Static Video File 310 mathematically represents a video recording as the algorithm “F_(w)=h_(x)l_(y)R_(v)G_(v)B_(v)t_(z)” and expressed in binary terms as: F₁=00001 00001 01110100 00000000 01011111 0000001 00100 00111 01001010 11111111 00000000 0000001 01011 10100 11101001 11100100 00000000 0000001; F₆=00100 00111 10001110 11000011 11101000 0000110; F₈=00001 00001 00000000 10001100 01110110 0001000; which mathematically represents a video recording whereby a shade of purple (R₁₁₆G₀₀₀B₀₉₅) is to be displayed within pixel h₁l₁ of a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, and F₇, then in video frame F₈ a shade of teal (R₀₀₀G₁₄₀B₁₁₈) is to be displayed within pixel h₁l₁; a shade of lime green (R₀₇₄G₂₅₅B₀₀₀) is to be displayed within pixel h₄₁₇ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, and F₅, then in video frames F₆, F₇, and F₈ a shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) is to be displayed within pixel h₄₁₇; and a shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) is to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ (see FIG. 18). As further clarification, said pixels h₁l₁, h₄l₇, and h₁₁l₂₀ are discussed below, detailing the process the Static Video Player 320 utilizes to replicate color information from the Static Video File 310 to the red/green/blue memory registers within the Static Video Player 320. The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₁ identify pixel h₁l₁; the “01110100 00000000 01011111” in the third, fourth, and fifth groups of the first set of binary information in the data string associated with video frame F₁ identify a shade of purple, being a complex color generated by the mixture of the basic colors R₁₁₆G₀₀₀B₀₉₅; and the “0000001” in the sixth group of the first set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to save the purple (R₁₁₆G₀₀₀B₀₉₅) color information into memory registers r_(1/1)g_(1/1)b_(1/1), and upon commencing the sequential serial transmission of color information by video frame from the Static Video File 310, the Static Video Player 320 replicates and saves color information related to video frame F₁ from the Static Video File 310 into the video frame buffer memory, including said “01110100 00000000 01011111” in said third, fourth, and fifth groups of said first set of binary information in said data string associated with video frame F₁, and then the Static Video Player 320 invokes a parallel data dump of all color information related to video frame F₁ from the video frame buffer memory to the red/green/blue memory registers, including said “01110100 00000000 01011111” in said third, fourth, and fifth groups of said first set of binary information in said data string associated with video frame F₁ which is saved in the r_(1/1)g_(1/1)b_(1/1) memory register within the Static Video Player 320 at time t₁. The “00001 00001” in the first and second groups of the only set of binary information in the data string associated with video frame F₈ identify pixel h₁l₁; the “00000000 10001100 01110110” in the third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₈ identify a shade of teal, being a complex color generated by the mixture of the basic colors R₀₀₀G₁₄₀B₁₁₈; and the “0001000” the sixth group of the only set of binary information in the data string associated with video frame F₈ identifies the time t₈ when the Static Video Player 320 is to save the teal (R₀₀₀G₁₄₀B₁₁₈) color information into memory registers r_(1/1)g_(1/1)b_(1/1), and when the sequential serial transmission of color information by video frame reaches the point when color information related to video frame F₈ is to be accessed from the Static Video File 310, the Static Video Player 320 replicates and saves color information related to video frame F₈ from the Static Video File 310 into the video frame buffer memory, including said “00000000 10001100 01110110” in said third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₈, and then the Static Video Player 320 invokes a parallel data dump of all color information related to video frame F₈ from the video frame buffer memory to the red/green/blue memory registers, including said “00000000 10001100 01110110” in said third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₈, which is saved in the r_(1/1)g_(1/1)b_(1/1) memory register within the Static Video Player 320 at time t₈. The “00100 00111” in the first and second groups of the second set of binary information in the data string associated with video frame F₁ identify pixel h₄l₇; the “01001010 11111111 00000000” in the third, fourth, and fifth groups of the second set of binary information in the data string associated with video frame F₁ identify a shade of lime green, being a complex color generated by the mixture of the basic colors R₀₇₄G₂₅₅B₀₀₀; and the “0000001” in the sixth group of the second set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to save the lime green (R₀₇₄G₂₅₅B₀₀₀) color information into memory registers r_(4/7)g_(4/7)b_(4/7), and upon commencing the sequential serial transmission of color information by video frame from the Static Video File 310, the Static Video Player 320 replicates and saves color information related to video frame F₁ from the Static Video File 310 into the video frame buffer memory, including said “01001010 11111111 00000000” in said third, fourth, and fifth groups of said second set of binary information in said data string associated with video frame F₁, and then the Static Video Player 320 invokes a parallel data dump of all color information related to video frame F₁ from the video frame buffer memory to the red/green/blue memory registers, including said “01001010 11111111 00000000” in said third, fourth, and fifth groups of said second set of binary information in said data string associated with video frame F₁, which is saved in the r_(4/7)g_(4/7)b_(4/7) memory register within the Static Video Player 320 at time t₁. The “00100 00111” in the first and second groups of the only set of binary information in the data string associated with video frame F₆ identify pixel h₄l₇; the “10001110 11000011 11101000” in the third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₆ identify a shade of powder blue, being a complex color generated by the mixture of the basic colors R₁₄₂G₁₉₅B₂₃₂; and the “0000110” the sixth group of the only set of binary information in the data string associated with video frame F₆ identifies the time t₆ when the Static Video Player 320 is to save the powder blue (R₁₄₂G₁₉₅B₂₃₂) color information into memory registers r_(4/7)g_(4/7)b_(4/7), and when the sequential serial transmission of color information by video frame reaches the point when color information related to video frame F₆ is to be accessed from the Static Video File 310, the Static Video Player 320 replicates and saves color information related to video frame F₆ from the Static Video File 310 into the video frame buffer memory, including said “10001110 11000011 11101000” in said third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₆, and then the Static Video Player 320 invokes a parallel data dump of all color information related to video frame F₆ from the video frame buffer memory to the red/green/blue memory registers, including said “10001110 11000011 11101000” in said third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₆, which is saved in the r_(4/7)g_(4/7)b_(4/7) memory register within the Static Video Player 320 at time t₆. The “01011 10100” in the first and second groups of the third set of binary information in the data string associated with video frame F₁ identify pixel h₁₁l₂₀; the “11101001 11100100 00000000” in the third, fourth, and fifth groups of the third set of binary information in the data string associated with video frame F₁ identify a shade of lemon yellow, being a complex color generated by the mixture of the basic colors R₂₃₃G₂₂₈B₀₀₀; and the “0000001” in the sixth group of the third set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 is to save the lemon yellow (R₂₃₃G₂₂₈B₀₀₀) color information into memory registers r_(11/20)g_(11/20)b_(11/20), and upon commencing the sequential serial transmission of color information by video frame from the Static Video File 310, the Static Video Player 320 replicates and saves color information related to video frame F₁ from the Static Video File 310 into the video frame buffer memory, including said “11101001 11100100 00000000” in said third, fourth, and fifth groups of said third set of binary information in said data string associated with video frame F₁, and then the Static Video Player 320 invokes a parallel data dump of all color information related to video frame F₁ from the video frame buffer memory to the red/green/blue memory registers, including said “11101001 11100100 00000000” in said third, fourth, and fifth groups of said third set of binary information in said data string associated with video frame F₁ which is saved in the r_(11/20)g_(11/20)b_(11/20) memory register within the Static Video Player 320 at time t₁.

Additionally, the invention utilizes the Static Video Player 320 to display, and/or replicate, color information saved from the Static Video File 350 into the red/green/blue memory registers in the Static Video Player 320 in a similar manner as mentioned above for the color information received by the Static Video Player 320 by the Static Video File 310. The Static Video Player 320 may receive color information from the Static Video File 350 via the Electronic Connection 340 in a download fashion or in a broadcast fashion. As example, in a download transmission, a sending computer system may create an electronic copy of a Static Video File 350 and transmit said Static Video File 350 serially by means of a conventional modem electronically connected to the Electronic Connection 340 and received by a receiving computer system by means of a conventional modem electronically connected to the Electronic Connection 340 and electronically stored in the hard disk of the receiving computer system (i.e. U.S. Pat. No. 5,191,573). Also as example, in a broadcast transmission, a sending computer system may create an electronic copy of a Static Video File 350 and transmit said Static Video File 350 serially, and at the normal display rate of the video recording, by means of a conventional modem electronically connected to the Electronic Connection 340 and received by a receiving computer system by means of a conventional modem electronically connected to the Electronic Connection 340 and subsequently transmitted by the receiving computer system to the video card of the receiving computer system for display on the Video Output Device 390.

When the Static Video Player 320 commences the display, and/or replication, process, whatever R_(v)G_(v)B_(v) color information has been saved within the video memory registers r_(x/y)g_(x/y)b_(x/y) will be displayed, and/or replicated, within the corresponding h_(x)l_(y) pixel on the Video Output Device 390. For each video frame F_(z), the Static Video Player 320 first saves any new R_(v)G_(v)B_(v) color information into the video memory registers r_(x/y)g_(x/y)b_(x/y), then the Static Video Player 320 displays complex colors, as generated by the color information in the video memory registers r_(x/y)g_(x/y)b_(x/y), within the corresponding pixels h_(x)l_(y) on the Video Output Device 390 at time t_(z) corresponding to video frame F_(w). For any video frame F_(w), if any memory register r_(x/y)g_(x/y)b_(x/y) is not updated by the Static Video Player 320 with new R_(v)G_(v)B_(v) color information from the Static Video File 310, then the R_(v)G_(v)B_(v) color information within any such memory register r_(x/y)g_(x/y)b_(x/y) will not be altered until the Static Video Player 320 receives updated R_(v)G_(v)B_(v) color information from the Static Video File 310 corresponding to said memory register r_(x/y)g_(x/y)b_(x/y). The Static Video Player 320 sequentially replicates, one video frame at a time, the color information contained in all of the red/green/blue memory registers into a video card buffer memory within the Static Video Player 320. The Static Video Player 320 then transmits said color information to the video card of the host computer. Upon receipt of the color information, said video card transmits said color information to the Video Output Device 390 for display. As example, the Static Video Player 320 invokes a parallel data dump of the color information related to the first video frame from the red/green/blue memory registers to a video card buffer memory within the Static Video Player 320. Next, the Static Video Player 320 accesses the video card buffer memory, sequentially by video frame and at the intended playback rate (i.e. 30 video frames per second for motion picture quality recordings), and invokes a parallel data dump of all of the color information related to said first video frame to said video card through an electronic connecting bus. Upon receipt of the color information related to said first video frame, said video card will transmit/relay, in either digital form or analog form, the color information related to said first video frame to the Video Output Device 390 for display. While the Static Video Player 320 invokes a parallel data replication of the color information related to said first video frame from the red/green/blue memory registers to said video card buffer memory, the Static Video Player 320 invokes a parallel data dump of the color information related to the second video frame from the video frame buffer memory (as mentioned hereinabove) to said red/green/blue memory registers. Then, while the Static Video Player 320 invokes a parallel data dump of the color information related to said first video frame from said video card buffer memory to said video card, the Static Video Player 320 invokes a parallel data replication of the color information related to the second video frame from said red/green/blue memory registers to said video card buffer memory. Then, while said video card transmits/relays the color information related to said first video frame to the Video Output Device 390 for display, the Static Video Player 320 invokes a parallel data dump of the color information related to said second video frame from said video card buffer memory to said video card through said electronic connecting bus. Upon receipt of the color information related to said second video frame, said video card will transmit/relay, in either digital form or analog form, the color information related to said second video frame to the Video Output Device 390 for display. The color information in the third video frame, forth video frame, fifth video frame, etc. will continue in the above manner until the end of the Static Video File 310.

Additionally, the Static Video Player 320 is capable of displaying, and/or replicating, color information in either digital video form or analog video form on the Video Output Device 390 within pixels h_(x)l_(y) corresponding to said video memory registers r_(x/y)g_(x/y)b_(x/y). Again, using the previous example where the Static Video File 310 mathematically represents a video recording as the algorithm “F_(w)=h_(x)l_(y)R_(v)G_(v)B_(v)t_(z)” and expressed in binary terms as: F₁=00001 00001 01110100 00000000 01011111 0000001 00100 00111 01001010 11111111 00000000 0000001 01011 10100 11101001 11100100 00000000 0000001; F₆=00100 00111 10001110 11000011 11101000 0000110; F₈=00001 00001 00000000 10001100 01110110 0001000; which mathematically represents a video recording (see FIG. 19) whereby a shade of purple (R₁₁₆G₀₀₀B₀₉₅) is to be displayed within pixel h₁l₁ of a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, and F₇, then in video frame F₈ a shade of teal (R₀₀₀G₁₄₀B₁₁₈) is to be displayed within pixel h₁l₁; a shade of lime green (R₀₇₄G₂₅₅B₀₀₀) is to be displayed within pixel h₄₁₇ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, and F₅, then in video frames F₆, F₇, and F₈ a shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) is to be displayed within pixel h₄₁₇; and a shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) is to be displayed within pixel h₁₁l₂₀ on a Video Output Device 390 in video frames F₁, F₂, F₃, F₄, F₅, F₆, F₇, and F₈ (see FIG. 11). The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₁ identify pixel h₁l₁; the “01110100 00000000 01011111” in the third, fourth, and fifth groups of the first set of binary information in the data string associated with video frame F₁ identify a shade of purple, being a complex color generated by the mixture of the basic colors R₁₁₆G₀₀₀B₀₉₅; and the “0000001” in the sixth group of the first set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 will commence to display within pixel h₁l₁ on the Video Output Device 390 commencing with video frame F₁ said shade of purple (R₁₁₆G₀₀₀B₀₉₅), as saved in time t₁ in the r_(1/1)g_(1/1)b_(1/1) memory registers which correspond to said pixel h₁l₁, and the Static Video Player 320 will continue to display said shade of purple (R₁₁₆G₀₀₀B₀₉₅) within pixel h₁l₁ on the Video Output Device 390 during video frames F₂, F₃, F₄, F₅, F₆, and F₇ since the Static Video File 310 does not have instructions for the Static Video Player 320 to alter said r_(1/1)g_(1/1)b_(1/1) memory registers during times t₂, t₃, t₄, t₅, t₆, and t₇. Upon commencing the sequential parallel data replication of color information by video frame from the red/green/blue memory registers to the video card buffer memory, the Static Video Player 320 invokes a sequential parallel data replication of color information related to video frame F₁ from the red/green/blue memory registers into the video card buffer memory, including said “01110100 00000000 01011111” in the r_(1/1)g_(1/1)b_(1/1) memory register. Next, the Static Video Player 320 invokes a parallel data dump of color information related to video frame F₁ from the video card buffer memory to the video card within the host computer system, including said “01110100 00000000 01011111” related to said pixel h₁l₁ in video frame F₁. Next, the video card relays/transmits said color information related to video frame F₁ to the corresponding pixels h_(x)l_(y) of the Video Output Device 390, including said shade of purple (R₁₁₆G₀₀₀B₀₉₅) to commence to be displayed within pixel h₁l₁ of the Video Output Device 390 time t₁. The “00001 00001” in the first and second groups of the first set of binary information in the data string associated with video frame F₈ identify pixel h₁l₁; the “00000000 10001100 01110110” in the third, fourth, and fifth groups of the first set of binary information in the data string associated with video frame F₈ identify a shade of teal, being a complex color generated by the mixture of the basic colors R₀₀₀G₁₄₀B₁₁₈; and the “0001000” in the sixth group of the first set of binary information in the data string associated with video frame F₈ identifies the time t₈ when the Static Video Player 320 will commence to display within pixel h₁l₁ on the Video Output Device 390 commencing with video frame F₈ said shade of teal (R₀₀₀G₁₄₀B₁₁₈), as saved in time t₈ in the r_(1/1)g_(1/1)b_(1/1) memory registers which correspond to said pixel h₁l₁. When the sequential parallel data replication of color information by video frame reaches the point when color information related to video frame F₈ is to be replicated to the video card buffer memory, the Static Video Player 320 invokes a sequential parallel data replication of color information related to video frame F₈ from the red/green/blue memory registers into the video card buffer memory, including said “00000000 10001100 01110110” in the r_(1/1)g_(1/1)b_(1/1) memory register. Next, the Static Video Player 320 invokes a parallel data dump of color information related to video frame F₈ from the video card buffer memory to the video card within the host computer system, including said “00000000 10001100 01110110” related to said pixel h₁l₁ in video frame F₈. Next, the video card relays/transmits said color information related to video frame F₈ to the corresponding pixels h_(x)l_(y) of the Video Output Device 390′, including said shade of teal (R₀₀₀G₁₄₀B₁₁₈) to commence to be displayed within pixel h₁l₁ of the Video Output Device 390 in time t₈. The “00100 00111” in the first and second groups of the second set of binary information in the data string associated with video frame F₁ identify pixel h₄₁₇; the “01001010 11111111 00000000” in the third, fourth, and fifth groups of the second set of binary information in the data string associated with video frame F₁ identify a shade of lime green, being a complex color generated by the mixture of the basic colors R₀₇₄G₂₅₅B₀₀₀; and the “0000001” in the sixth group of the second set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 will commence to display within pixel h₄l₇ on the Video Output Device 390 commencing with video frame F said shade of lime green (R₀₇₄G₂₅₅B₀₀₀), as saved in time t₁ in the r_(4/7)g_(4/7)b_(4/7) memory registers which correspond to said pixel h₄₁₇, and the Static Video Player 320 will continue to display said shade of lime green (R₀₇₄G₂₅₅B₀₀₀) within pixel h₄l₇ on the Video Output Device 390 during video frames F₂, F₃, F₄, and F₅ since the Static Video File 310 does not have instructions for the Static Video Player 320 to alter said r_(4/7)g_(4/7)b_(4/7) memory registers during times t₂, t₃, t₄, and t₅. Upon commencing the sequential parallel data replication of color information by video frame from the red/green/blue memory registers to the video card buffer memory, the Static Video Player 320 invokes a sequential parallel data replication of color information related to video frame F₁ from the red/green/blue memory registers into the video card buffer memory, including said “01001010 11111111 00000000” in the r_(4/7)g_(4/7)b_(4/7) memory register. Next, the Static Video Player 320 invokes a parallel data dump of color information related to video frame F₁ from the video card buffer memory to the video card within the host computer system, including said “01001010 11111111 00000000” related to said pixel h₄₁₇ in video frame F₁. Next, the video card relays/transmits said color information related to video frame F₁ to the corresponding pixels h_(x)l_(y) of the Video Output Device 390, including said shade of lime green (R₀₇₄G₂₅₅B₀₀₀) to commence to be displayed within pixel h₄l₇ of the Video Output Device 390 time t₁. The “00100 00111” in the first and second groups of the only set of binary information in the data string associated with video frame F₆ identify pixel h₄₁₇; the “10001110 11000011 11101000” in the third, fourth, and fifth groups of the only set of binary information in the data string associated with video frame F₆ identify a shade of powder blue, being a complex color generated by the mixture of the basic colors R₁₄₂G₁₉₅B₂₃₂; and the “0000110” in the sixth group of the only set of binary information in the data string associated with video frame F₆ identifies the time t₆ when the Static Video Player 320 will commence to display within pixel h₄₁₇ on the Video Output Device 390 commencing with video frame F₆ said shade of powder blue (R₁₄₂G₁₉₅B₂₃₂), as saved in time t₆ in the r_(4/7)g_(4/7)b_(4/7) memory registers which correspond to said pixel h₄₁₇, and the Static Video Player 320 will continue to display said shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) within pixel h₄₁₇ on the Video Output Device 390 during video frames F₇ and F₈ since the Static Video File 310 does not have instructions for the Static Video Player 320 to alter said r_(4/7)g_(4/7)b_(4/7) memory registers during times t₇ and t₈. When the sequential parallel data replication of color information by video frame reaches the point when color information related to video frame F₆ is to be replicated to the video card buffer memory, the Static Video Player 320 invokes a sequential parallel data replication of color information related to video frame F₈ from the red/green/blue memory registers into the video card buffer memory, including said “10001110 11000011 11101000” in the r_(4/7)g_(4/7)b_(4/7) memory register. Next, the Static Video Player 320 invokes a parallel data dump of color information related to video frame F₆ from the video card buffer memory to the video card within the host computer system, including said “10001110 11000011 11101000” related to said pixel h₄l₇ in video frame F₆. Next, the video card relays/transmits said color information related to video frame F₆ to the corresponding pixels h_(x)l_(y) of the Video Output Device 390, including said shade of powder blue (R₁₄₂G₁₉₅B₂₃₂) to commence to be displayed within pixel h₄l₇ of the Video Output Device 390 in time t₆. The “01011 10100” in the first and second groups of the third set of binary information in the data string associated with video frame F₁ identify pixel h₁₁l₂₀; the “11101001 11100100 00000000” in the third, fourth, and fifth groups of the third set of binary information in the data string associated with video frame F₁ identify a shade of lemon yellow, being a complex color generated by the mixture of the basic colors R₂₃₃G₂₂₈B₀₀₀; and the “0000001” in the sixth group of the third set of binary information in the data string associated with video frame F₁ identifies the time t₁ when the Static Video Player 320 will commence to display within pixel h₁₁l₂₀ on the Video Output Device 390 commencing with video frame F₁ said shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀), as saved in time t₁ in the r_(11/20)g_(11/20)b_(11/20) memory registers which correspond to said pixel h₁₁l₂₀, and the Static Video Player 320 will continue to display said shade of lemon yellow (R₂₃₃G₂₂₈B₀₀₀) within pixel h₁₁l₂₀ on the Video Output Device 390 during video frames F₂, F₃, F₄, F₅, F₆, F₇, and F₈ since the Static Video File 310 does not have instructions for the Static Video Player 320 to alter said r_(11/20)g_(11/20)b_(11/20) memory registers during times t₂, t₃, t₄, t₅, t₆, t₇, and t₈. Upon commencing the sequential parallel data replication of color information by video frame from the red/green/blue memory registers to the video card buffer memory, the Static Video Player 320 invokes a sequential parallel data replication of color information related to video frame F₁ from the red/green/blue memory registers into the video card buffer memory, including said “11101001 11100100 00000000” in the r_(11/20)g_(11/20)b_(11/20) memory register. Next, the Static Video Player 320 invokes a parallel data dump of color information related to video frame F₁ from the video card buffer memory to the video card within the host computer system, including said “11101001 11100100 00000000” related to said pixel h₁₁l₂₀ in video frame F₁. Next, the video card relays/transmits said color information related to video frame F₁ to the corresponding pixels h_(x)l_(y) of the Video Output Device 390, including said shade of lime green (R₀₇₄G₂₅₅B₀₀₀) to commence to be displayed within pixel h₁₁l₂₀ of the Video Output Device 390 time t₁.

As discussed above, the color information saved in the r_(1/1)g_(1/1)b_(1/1) memory registers within in the Static Video Player 320 can be obtained from the Static Video File 310 one video frame at a time during real-time playback of the video recording or the Static Video Player 320 can obtain and schedule color information changes for all video frames F_(w) in the video recording, by pixel h_(x)l_(y) from the Static Video File 310 at, or before, the commencement of playback of the video recording, or a combination thereof.

Furthermore, and as example, if the Static Video Player 320 is displaying within a pixel h_(x)l_(y) on a Video Output Device 390 a complex color, and the difference between said complex color and the new complex color is due only to a change in the shade of the basic color green G_(v), and the shades of the basic colors red R_(v) and blue B_(v) do not change, then the Static Video File 310 could only be required to contain new information as to the basic color green G_(v), and the Static Video Player 320 could only be required to replace the green g_(x/y) memory register within the Static Video Player 320 related to said pixel h_(x)l_(y), with the green color information G_(v) from the Static Video File 310, thereby enabling the Static Video Player 320 to subsequently display, and/or replicate, the new specific complex color within said pixel h_(x)l_(y) on the Video Output Device 390.

Additionally, the Static Video Player 320 can be configured to contain one or more memory registers corresponding to each discrete pixel h_(x)l_(y), in which information from the Static Video File 310 can be saved. As example, the red/green/blue information may be configured to be saved in only one memory register corresponding with a pixel h_(x)l_(y) rather than to the individual r_(1/1)g_(1/1)b_(1/1) memory registers.

Additionally, if a video recording contains a situation in which a specific color is to be displayed within a plurality of contiguous pixels, forming a geometric shape, on a Video Output Device 390 commencing with a specific video frame F_(w), instead of recording the entire volume of said geometric shape within the Static Video File 310, only the corners (either interior or exterior corners) of said geometric shape could be recorded within the Static Video File 310 along with information instructing the Static Video Player 320 to colorized with said specific color the pixels h_(x)l_(y) within said geometric shape. By means of example (see Geometric Shape 1 in FIG. 20), video frame F₅₆ of a video recording contains a grouping of contiguous pixels which form a rectangle (Geometric Shape 1) with corners located at pixels h₃l₅, h₃l₁₈, h₈l₁₈, and h₈l₅ in which the complex color red (R₂₅₅G₀₀₀B₀₀₀) is to commence to be displayed in time t₅₆. The color information within the Static Video File 310, with respect to said red colored rectangle within said video frame F₅₆ is encoded to contain only said 4 corner pixels h₃l₅, h₃l₁₈, h₈l₁₈, and h₈l₅, instead of the 84 individual pixels within the volume of said red (R₂₅₅G₀₀₀B₀₀₀) rectangle, and the Static Video Player 320 would save the complex color red (R₂₅₅G₀₀₀B₀₀₀) in the video memory registers r_(x/y)g_(x/y)b_(x/y) corresponding to all pixels within the volume of the rectangle defined by the corners occupying pixels h₃l₅, h₃l₁₈, h₈l₁₈, and h₈l₅. To accomplish this, the algorithm “F_(x)=h_(x)l_(y)R_(v)G_(v)B_(v)t_(z)” as used in the previous example detailing how a Static Video File 310 could be encoded, would be modified to become the algorithm “F_(x)=h_(x)l_(y) . . . h_(x)l_(y)S_(j)R_(v)G_(v)B_(v)t_(z)” where the “h_(x)l_(y) . . . h_(x)l_(y)” identifies an unlimited plurality, or groupings, of pixels within a set of binary information in a data string associated with a video frame F₅₆, and the “S₀” identifies a code, expressed in binary terms as S₀=0000000000, which informs the Static Video Player 320 that the preceding groups of data identified the pixels which correspond to the corners of the red rectangle. Therefore, said algorithm “F_(x)=h_(x)l_(y) . . . h_(x)l_(y)S₀R_(v)G_(v)B_(v)t_(z)” for the preceding Geometric Shape 1 would be mathematically expressed as “F₅₆=h₃l₅h₃l₁₈h₈l₁₈h₈l₅S₀R₂₅₅G₀₀₀B₀₀₀t₅₆” and would be expressed in binary terms as: F₅₆=00000011 00000101 00000011 00010010 00001000 00010010 00001000 00000101 0000000000 11111111 00000000 00000000 0111000. Again by means of example (see Geometric Shape 2 in FIG. 20), video frame F₅₆ of a video recording contains a grouping of contiguous pixels which form an irregularly shaped polygon with corners located at pixels h₁₂l₃, h₁₂l₄, h₁₅l₄, h₁₅l₇, h₁₄l₇, h₁₄l₈, h₁₇l₈, h₁₇l₆, h₂₀l₆, h₂₀l₅, h₁₆l₅, and h₁₆l₃ in which the complex color blue (R₀₀₀G₀₀₀B₂₅₅) is to commence to be displayed in time t₅₆. The color information within the Static Video File 310, with respect to said blue colored irregularly shaped polygon within said video frame F₅₆ is encoded to contain only said 12 corner pixels h₁₂l₃, h₁₂l₄, h₁₅l₄, h₁₅l₇, h₁₄l₇, h₁₄l₈, h₁₇l₈, h₁₇l₆, h₂₀l₆, h₂₀l₅, h₁₆l₅, and h₁₆l₃, instead of the 30 individual pixels within the volume of said blue (R₀₀₀G₀₀₀B₂₅₅) irregularly shaped polygon (Geometric Shape 2), and the Static Video Player 320 would save the complex color blue (R₀₀₀G₀₀₀B₂₅₅) in the video memory registers r_(x/y)g_(x/y)b_(x/y) corresponding to all pixels within the volume of the irregularly shaped polygon defined by the corners occupying pixels h₁₂l₃, h₁₂l₄, h₁₅l₄, h₁₅l₇, h₁₄l₇, h₁₄l₈, h₁₇l₈, h₁₇l₆, h₂₀l₆, h₂₀l₅, h₁₆l₅, and h₁₆l₃. To accomplish this, the algorithm “F_(x)=h_(x)l_(y)R_(v)G_(v)B_(v)t_(z)” as used in the previous example detailing how a Static Video File 310 could be encoded, would be modified to become the algorithm “F_(x)=h_(x)l_(y) . . . h_(x)l_(y)S_(j)R_(v)G_(v)B_(v)t_(z)” where the “h_(x)l_(y) . . . h_(x)l_(y)” identifies an unlimited plurality, or groupings, of pixels within a set of binary information in a data string associated with a video frame F₅₆, and the “S₀” identifies a code, expressed in binary terms as S₀=0000000000, which informs the Static Video Player 320 that the preceding groups of data identified the pixels which correspond to the corners of the blue irregularly shaped polygon. Therefore, said algorithm “F_(x)=h_(x)l_(y) . . . h_(x)l_(y)S₀R_(v)G_(v)B_(v)t_(z)” for the preceding Geometric Shape 2 would be mathematically expressed as “F₅₆=h₁₂l₃h₁₂l₄h₁₅l₄h₁₅l₇h₁₄l₇h₁₄l₈ h₁₇l₈h₁₇l₆h₂₀l₆h₂₀l₅h₁₆l₅h₁₆l₃S₀R₀₀₀G₀₀₀B₂₅₅t₅₆” and would be expressed in binary terms as: F₅₆=00001100 00000011 00001100 00000100 00001111 00000100 00001111 00000111 00001110 00000111 00001110 00001000 00010001 00001000 00010001 00000110 00010100 00000110 00010100 00000101 00010000 00000101 00010000 00000011 0000000000 00000000 00000000 11111111 0111000. Additionally, and to add efficiency to the encoding process, the Static Video File 310 can be structured to accommodate a “layering” or “overlapping” of geometric shapes within an individual video frame F_(w). The encoding of a single video frame F_(w) of a Static Video File 310 can be separated into a plurality of video sub frames F_(w) ^(s), where the superscript “s” identifies a range of video sub frames for said video frame F_(w). As example, commencing with a specific video frame F_(w) of a video recording in which a Video Output Device 390 is to display a second specific color within a plurality of contiguous pixels forming a second geometric shape, said second geometric shape being located within a first geometric shape formed by a plurality of contiguous pixels in which a Video Output Device 390 is to display a first specific color, and said second geometric shape occupies some common pixels as does said first geometric shape. To accomplish this, color information related to said first geometric shape is encoded in a video sub frame F_(w) ¹ of the Static Video File 310, where the superscript “1” identifies the first layer, or first video sub frame, of video frame F_(w); next the color information related to said second geometric shape is encoded in a video sub frame F_(w) ² of the Static Video File 310, where the superscript “2” identifies the second layer, or second video sub frame, of video frame F_(w). The Static Video Player 320 is capable of building a single video frame F_(w) from a plurality of video sub frames F_(w), where the superscript “s” identifies a range of video sub frames for a single video frame F_(w). The Static Video Player 320 invokes a sequential serial transmissions of color information related to said video sub frame F_(w) ¹ from the Static Video File 310 into the video frame buffer memory; next the Static Video Player 320 invokes a parallel data dump of color information related to said video sub frame F_(w) ¹ from the video frame buffer memory into the red/green/blue memory registers; as the Static Video Player 320 invokes a parallel data dump of color information related to said video sub frame F_(w) ¹ from the video frame buffer memory into the red/green/blue memory registers, the Static Video Player 320 also invokes a sequential serial transmissions of color information related to said video sub frame F_(w) ² from the Static Video File 310 into the video frame buffer memory; before the Static Video Player 320 invokes a parallel data dump of color information related to said video frame F_(w) from red/green/blue memory registers into the video card buffer memory, the Static Video Player 320 invokes a parallel data dump of color information related to said video sub frame F_(w) ² from the video frame buffer memory into the red/green/blue memory registers, thus building said video frame F_(w) in layers. Further detailing this example (see Geometric Shapes 3 & 4 in FIG. 20), video frame F₅₆ of a video recording contains two geometric shapes, an irregularly shaped polygon (Geometric Shape 3) and a single pixel (Geometric Shape 4) within said irregularly shaped polygon. An irregularly shaped polygon with corners occupying pixels h₁₂l₂₀, h₁₉l₂₀, h₁₉l₂₂, h₂₀l₂₂, h₂₀l₁₉, h₂₂l₁₉, h₂₂l₁₈, h₁₉l₁₈, h₁₉l₁₅, and h₁₇l₁₅ of a Video Output Device 390 in which the complex color green (R₀₀₀G₂₅₅B₀₀₀) is to commence to be displayed in time t₅₆. Additionally, the complex color black (R₀₀₀G₀₀₀B₀₀₀) is to commence to be displayed in a single pixel h₁₈l₁₈ of a Video Output Device 390, also in time t₅₆. To build video frame F₅₆, the algorithm “F_(x)=h_(x)l_(y) . . . h_(x)l_(y)S_(j)R_(v)B_(v)t_(z)” would be used twice with respect to Geometric Shapes 3 & 4. Therefore, video frame F₅₆ would be mathematically expressed as “F₅₆ ¹=h₁₂l₂₀h₁₉l₂₀h₁₉l₂₂h₂₀l₂₂h₂₀l₁₉h₂₂l₁₉h₂₂l₁₈h₁₉l₁₈h₁₉l₁₅h₁₇l₁₅S₀ R₀₀₀G₂₅₅B₀₀₀t₅₆+F₅₆ ²=h₁₈l₁₈S₀R₀₀₀ G₀₀₀B₀₀₀t₅₆” and video frame F₅₆ would be expressed in binary terms as: F₅₆ ¹=00001100 00010100 00010011 00010100 00010011 00010110 00010100 00010110 00010100 00010011 00010110 00010011 00010110 00010010 00010011 00010010 00010011 00001111 00010001 00001111 0000000000 00000000 11111111 00000000 0111000; F₅₆ ²=00010010 00010010 0000000000 00000000 00000000 00000000 0111000.

The analyzing mechanism for the system above can alternatively include the frequency/amplitude database compiler 80 and the dynamic to static audio truncator 100, or the red/green/blue database compiler 280 and the dynamic to static video truncator 300. The playing mechanism can include a static audio file and a static audio player 120 and an audio output device, or a static video file 310 and a static video player 320 and a video output device.

Although the invention has been described in detail in the foregoing embodiments for the purpose of illustration, it is to be understood that such detail is solely for that purpose and that variations can be made therein by those skilled in the art without departing from the spirit and scope of the invention except as it may be described by the following claims. 

1. A system for manipulation of video signals comprising: a memory mechanism having color information by pixel by video frame of the video signal; an analyzing mechanism for analyzing color information by pixel by video frame of the video signal and identifying redundancies in the video signal over multiple and consecutive video frames, said analyzing mechanism in communication with said memory mechanism; and a playing mechanism for playing said video signal, said playing mechanism in communication with said memory mechanism and said analyzing mechanism, said playing mechanism using the redundancies to reduce the video signal as it is played compared to how it is saved in the memory mechanism, with the video signal being played as it would otherwise be played had the video signal been played as saved in the memory mechanism.
 2. A system as described in claim 1 wherein the planning mechanism is remote from the analyzing mechanism.
 3. A system as described in claim 2 wherein the playing mechanism includes telecommunication lines in communication with the analyzing mechanism.
 4. A system as described in claim 3 wherein the playing mechanism includes a color entry mechanism for providing pixels with a specific color.
 5. A system as described in claim 4 wherein the playing mechanism includes a controller for playing desired colors of corresponding pixels from the color entry mechanism based on their corresponding starting point, said controller in communication with the color entry mechanism in the analyzing mechanism.
 6. A method for manipulating video signals comprising the steps of: receiving a video signal; converting the video signal into a digital signal; storing the digital signal in the memory mechanism; playing the video signal based on the color of its pixel in its first video frame with a playing mechanism; identifying redundancies in the video signal over multiple and consecutive video frames with an analyzing mechanism, said analyzing mechanism in communication with said memory mechanism; and using the redundancies to reduce the video signal as it is played compared to how it is saved in the memory mechanism, with the video signal being played as it would otherwise be played had the video signal been played as saved in the memory mechanism.
 7. A system for manipulation of audio signals comprising: a memory mechanism having frequency/amplitude information by time interval of the audio signal; an analyzing mechanism for analyzing frequency/amplitude information by time interval of the audio signal and identifying redundancies in the audio signal over multiple and consecutive time intervals, said analyzing mechanism in communication with said memory mechanism; and a playing mechanism for playing said audio signal, said playing mechanism in communication with said memory mechanism and said analyzing mechanism, said playing mechanism using the redundancies to reduce the audio signal as it is played compared to how it is saved in the memory mechanism, with the audio signal being played as it would otherwise be played had the audio signal been played as saved in the memory mechanism.
 8. A method for manipulating audio signals comprising the steps of: receiving an audio signal; converting the audio signal into a digital signal; storing the digital signal in the memory mechanism; playing the audio signal based on frequency/amplitude of its first time interval with a playing mechanism; identifying redundancies in the audio signal over multiple and consecutive time intervals with an analyzing mechanism, said analyzing mechanism in communication with said memory mechanism; and using the redundancies to reduce the audio signal as it is played compared to how it is saved in the memory mechanism, with the audio signal being played as it would otherwise be played had the audio signal been played as saved in the memory mechanism. 